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by Sayer Ji from GreenMedInfo Website
New Perspectives on Celiac Disease and Wheat Intolerance July 17, 2009
The globe-spanning presence of wheat and its exalted status among secular and sacred institutions alike differentiates this food from all others presently enjoyed by humans.
Yet the unparalleled rise of wheat as the very catalyst for the emergence of ancient civilization has not occurred without a great price.
While wheat was the engine of civilization’s expansion and was glorified as a “necessary food,” both in the physical (staff of life) and spiritual sense (the body of Christ), those suffering from celiac disease are living testimony to the lesser known dark side of wheat.
A study of celiac disease and may help unlock the mystery of why modern man, who dines daily at the table of wheat, is the sickest animal yet to have arisen on this strange planet of ours.
THE CELIAC ICEBERG
Celiac disease (CD) was once considered an extremely rare affliction, limited to individuals of European origin.
Today, however, a growing number of studies indicate that celiac disease is found throughout the US at a rate of up to 1 in every 133 persons, which is several orders of magnitude higher than previously estimated.
These findings have led researchers to visualize CD as an iceberg. The tip of the iceberg represents the relatively small number of the world’s population whose gross presentation of clinical symptoms often leads to the diagnosis of celiac disease.
This is the classical case of CD characterized by,
It is confirmed with the “gold standard” of an intestinal biopsy.
The submerged middle portion of the iceberg is largely invisible to classical clinical diagnosis, but not to modern serological screening methods in the form of antibody testing. This middle portion is composed of asymptomatic and latent celiac disease as well as “out of the intestine” varieties of wheat intolerance.
Finally, at the base of this massive iceberg sits approximately 20-30% of the world’s population - those who have been found to carry the HLA-DQ locus of genetic susceptibility to celiac disease on chromosome 6.*
* Genome screening of coeliac disease
The “Celiac Iceberg” may not simply illustrate the problems and issues associated with diagnosis and disease prevalence, but may represent the need for a paradigm shift in how we view both CD and wheat consumption among non-CD populations.
First let us address the traditional view of CD as a rare, but clinically distinct species of genetically-determined disease, which I believe is now running itself aground upon the emerging, post-Genomic perspective, whose implications for understanding and treating disease are Titanic in proportion.
IT IS NOT THE GENES, BUT WHAT WE EXPOSE THEM TO
Despite common misconceptions, monogenic diseases, or diseases that result from errors in the nucleotide sequence of a single gene are exceedingly rare.
Perhaps only 1% of all diseases fall within this category, and Celiac disease is not one of them. In fact, following the completion of the Human Genome Project (HGP) in 2003 it is no longer accurate to say that our genes “cause” disease, any more than it is accurate to say that DNA is sufficient to account for all the proteins in our body.
Despite initial expectations, the HGP revealed that there are only 20,000-25,000 genes in human DNA (genome), rather than the 100,000 + believed necessary to encode the 100,000 + proteins found in the human body (proteome).
The “blueprint” model of genetics:
...which was once the holy grail of biology, has now been supplanted by a model of the cell where epigenetic factors (literally: “beyond the control of the gene”) are primary in determining how DNA will be interpreted, translated and expressed.
A single gene can be used by the cell to express a multitude of proteins and it is not the DNA itself that determines how or what genes will be expressed.
Rather, we must look to the epigenetic factors to understand what makes a liver cell different from a skin cell or brain cell. All of these cells share the exact same 3 billion base pairs that make up our DNA code, but it is the epigenetic factors, e.g. regulatory proteins and post-translational modifications, that make the determination as to which genes to turn on and which to silence, resulting in each cell’s unique phenotype.
Moreover, epigenetic factors are directly and indirectly influenced by the presence or absence of key nutrients in the diet, as well as exposures to chemicals, pathogens and other environmental influences.
In a nutshell, what we eat and what we are exposed to in our environment directly affects our DNA and its expression.
Within the scope of this new perspective even classical monogenic diseases like Cystic Fibrosis (CF) can be viewed in a new, more promising light.
In CF many of the adverse changes that result from the defective expression of the Cystic Fibrosis Transmembrane Conductance Regulator (CFTR) gene may be preventable or reversible, owing to the fact that the misfolding of the CFTR gene product has been shown to undergo partial or full correction (in the rodent model) when exposed to phytochemicals found in turmeric, cayenne, and soybean.
Moreover, nutritional deficiencies of selenium, zinc, riboflavin, vitamin E, etc. in the womb or early in life, may “trigger” the faulty expression or folding patterns of the CFTR gene in Cystic Fibrosis which might otherwise have avoided epigenetic activation.
This would explain why it is possible to live into one’s late seventies with this condition, as was the case for Katherine Shores (1925-2004). The implications of these findings are rather extraordinary:
Even if we exclude the possibility of reversing certain monogenic diseases, the basic lesson from the post-Genomic era is that we can’t blame our DNA for causing disease.
Rather, it may have more to do with what we choose to expose our DNA to.
CELIAC DISEASE REVISITED
What all of this means for CD is that the genetic susceptibility locus, HLA DQ, does not determine the exact clinical outcome of the disease. Instead of being the cause, if the HLA genes are activated, they are a consequence of the disease process.
Thus, we may need to shift our epidemiological focus from viewing this as a classical “disease” involving a passive subject controlled by aberrant genes, to viewing it as an expression of a natural, protective response to the ingestion of something that the human body was not designed to consume.
If we view celiac disease not as an unhealthy response to a healthy food, but as a healthy response to an unhealthy food, classical CD symptoms like diarrhea may make more sense. Diarrhea can be the body’s way to reduce the duration of exposure to a toxin or pathogen, and villous atrophy can be the body’s way of preventing the absorption and hence, the systemic effects of chronic exposure to wheat.
I believe we would be better served by viewing the symptoms of CD as expressions of bodily intelligence rather than deviance. We must shift the focus back to the disease trigger, which is wheat itself.
People with celiac may actually have an advantage over the apparently unafflicted because those who are “non-symptomatic” and whose wheat intolerance goes undiagnosed or misdiagnosed because they lack the classical symptoms and may suffer in ways that are equally or more damaging, but expressed more subtly, or in distant organs.
Within this view celiac disease would be redefined as a protective (healthy?) response to exposure to an inappropriate substance, whereas “asymptomatic” ingestion of the grain with its concomitant “out of the intestine” and mostly silent symptoms, would be considered the unhealthy response insofar as it does not signal in an obvious and acute manner that there is a problem with consuming wheat.
It is possible that celiac disease represents both an extreme reaction to a global, species-specific intolerance to wheat that we all share in varying degrees. CD symptoms may reflect the body’s innate intelligence when faced with the consumption of a substance that is inherently toxic.
Let me illustrate this point using Wheat Germ Agglutinin (WGA), as an example.
WGA is classified as a lectin and is known to play a key role in kidney pathologies, such as IgA nephropathy.
In the article: “Do dietary lectins cause disease?” the Allergist David L J Freed points out that WGA binds to,
Indeed, a study from the Mario Negri Institute for Pharmacological Research in Milan Italy published in 2007 in the International Journal of Cancer looked at bread consumption and the risk of kidney cancer.
They found that those who consumed the most bread had a 94% higher risk of developing kidney cancer compared to those who consumed the least bread.
Given the inherently toxic effect that WGA may have on kidney function, it is possible that in certain genetically predisposed individuals (e.g. HLA-DQ2/DQ8) the body - in its innate intelligence - makes an executive decision:
This is the explanation typically given for the body’s reflexive formation of mucous following exposure to certain highly allergenic or potentially toxic foods, e.g. dairy products, sugar, etc?
The mucous coats the offending substance, preventing its absorption and facilitating safe elimination via the gastrointestinal tract. From this perspective the HLA-DQ locus of disease susceptibility in the celiac is not simply activated but utilized as a defensive adaptation to continual exposure to a harmful substance.
In those who do not have the HLA-DQ locus, an autoimmune destruction of the villi will not occur as rapidly, and exposure to the universally toxic effects of WGA will likely go unabated until silent damage to distant organs leads to the diagnosis of a disease that is apparently unrelated to wheat consumption.
Loss of kidney function may only be the “tip of the iceberg,” when it comes to the possible adverse effects that wheat proteins and wheat lectin can generate in the body. If kidney cancer is a likely possibility, then other cancers may eventually be linked to wheat consumption as well.
This correlation would fly in the face of globally sanctioned and reified assumptions about the inherent benefits of wheat consumption. It would require that we suspend cultural, socio-economic, political and even religious assumptions about its inherent benefits.
In many ways, the reassessment of the value of wheat as a food requires a William Boroughs-like moment of shocking clarity when we perceive,
Let’s take a closer look at what is on the end of our forks.
OUR BIOLOGICALLY INAPPROPRIATE DIET
In a previous article, I discussed the role that wheat plays as an industrial adhesive (e.g. paints, paper mache’, and book binding-glue) in order to illustrate the point that it may not be such a good thing for us to eat.
The problem is implicit in the word gluten, which literally means “glue” in Latin and in words like pastry and pasta, which derives from wheatpaste, the original concoction of wheat flour and water which made such good plaster in ancient times. What gives gluten its adhesive and difficult-to-digest qualities are the high levels of disulfide bonds it contains.
These same sulfur-to-sulfur bonds are found in hair and vulcanized rubber products, which we all know are difficult to decompose and are responsible for the sulfurous odor they give off when burned.
There will be 676 million metric tons of wheat produced this year alone, making it the primary cereal of temperate regions and third most prolific cereal grass on the planet.
This global dominance of wheat is signified by the Food & Agricultural Organization’s (FAO) (the United Nation’s international agency for defeating hunger) use of a head of wheat as its official symbol. Any effort to indict the credibility of this “king of grains” will prove challenging.
As Rudolf Hauschka once remarked, wheat is “a kind of earth-spanning organism.” It has vast socio-economic, political, and cultural significance.
For example, in the Catholic Church, a wafer made of wheat is considered irreplaceable as the 'embodiment' of Christ.
Our dependence on wheat is matched only by its dependence on us.
As Europeans have spread across the planet, so has this grain. We have assumed total responsibility for all phases of the wheat life cycle:
We have become so inextricably interdependent that neither species is sustainable at current population levels without this symbiotic relationship.
It is this codependence that may explain why our culture has for so long consistently confined wheat intolerance to categorically distinct, “genetically-based” diseases like “celiac.”
These categorizations may protect us from the realization that wheat exerts a vast number of deleterious effects on human health in the same way that “lactose intolerance” distracts attention from the deeper problems associated with the casein protein found in cow’s milk.
Rather than see wheat for what it very well may be:
The medical justification for these classifications may be secondary to economic and cultural imperatives that require the inherent problems associated with wheat consumption be minimized or occluded.
In all probability the celiac genotype represents a surviving vestigial branch of a once universal genotype, which through accident or intention, have had through successive generations only limited exposure to wheat.
The celiac genotype, no doubt, survived through numerous bottlenecks or “die offs” represented by a dramatic shift from hunted and foraged/gathered foods to gluten-grain consumption, and for whatever reason simply did not have adequate time to adapt or select out the gluten-grain incompatible genes.
The celiac response may indeed reflect a prior, species-wide intolerance to a novel food source: the seed storage form of the monocotyledonous cereal grasses which our species only began consuming 1-500 generations ago at the advent of the Neolithic transition (10-12,000 BC).
Let us return to the image of the celiac iceberg for greater clarification.
OUR SUBMERGED GRAIN-FREE METABOLIC PREHISTORY
The iceberg metaphor is an excellent way to expand our understanding of what was once considered to be an extraordinarily rare disease into one that has statistical relevance for us all, but it has a few limitations.
For one, it reiterates the commonly held view that Celiac is a numerically distinct disease entity or “disease island,” floating alongside other numerically distinct disease “ice cubes” in the vast sea of normal health. Though accurate in describing the sense of social and psychological isolation many of the afflicted feel, the celiac iceberg/condition may not be a distinct disease entity at all.
Although the HLA-DQ locus of disease susceptibility on chromosome 6 offers us a place to project blame, I believe we need to shift the emphasis of responsibility for the condition back to the disease “trigger” itself:
Without these grains the typical afflictions we call celiac would not exist.
Within the scope of this view the “celiac iceberg” is not actually free floating but an outcropping from an entire submerged subcontinent, representing our long-forgotten (cultural time) but relatively recent metabolic prehistory as hunters-and-gatherers (biological time), where grain consumption was, in all likelihood, non-existent, except in instances of near-starvation.
The pressure on the celiac to be viewed as an exceptional case or deviation may have everything to do with our preconscious belief that wheat, and grains as a whole are the “health foods,” and very little to do with a rigorous investigations of the facts.
Grains have been heralded since time immemorial as the “staff of life,” when in fact they are more accurately described as a cane, precariously propping up a body starved of the nutrient-dense, low-starch vegetables, fruits, edible seeds and meats, they have so thoroughly supplanted (c.f. Paleolithic Diet).
Most of the diseases of affluence, e.g.,
...can be linked to the consumption of a grain-based diet, including secondary “hidden sources” of grain consumption in grain-fed fish, poultry, meat and milk products.
Our modern belief that grains make for good food, is simply not supported by the facts.
The cereal grasses are within an entirely different family: monocotyledonous (one leaf) than that from which our body sustained itself for millions of years: dicotyledonous (two-leaf). The preponderance of scientific evidence points to a human origin in the tropical rainforests of Africa where dicotyledonous fruits would have been available for year round consumption.
It would not have been monocotyledonous plants, but the flesh of hunted animals that would have allowed for the migration out of Africa 60,000 years ago into the northern latitudes where vegetation would have been sparse or non-existent during winter months.
Collecting and cooking grains would have been improbable given the low nutrient and caloric content of grains and the inadequate development of pyrotechnology and associated cooking utensils necessary to consume them with any efficiency.
It was not until the end of the last Ice Age 20,000 years ago that our human ancestors would have slowly transitioned to a cereal grass based diet coterminous with emergence of civilization. 20,000 years is probably not enough time to fully adapt to the consumption of grains.
Even animals like cows with a head start of thousands of years, having evolved to graze on monocotyledons and equipped as ruminants with the four-chambered fore-stomach enabling the breakdown of cellulose and anti-nutrient rich plants, are not designed to consume grains.
Cows are designed to consume the sprouted mature form of the grasses and not their seed storage form. Grains are so acidic/toxic in reaction that exclusively grain-fed cattle are prone to developing severe acidosis and subsequent liver abscesses and infections, etc.
Feeding wheat to cattle provides an even greater challenge:
Seeds, after all, are the "babies" of these plants, and are invested with not only the entire hope for continuance of its species, but a vast armory of anti-nutrients to help it accomplish this task:
These not so appetizing phytochemicals enable plants to resist predation of their seeds, or at least preventing them from "going out without a punch."
WHEAT - AN EXCEPTIONALLY UNWHOLESOME GRAIN
Wheat presents a special case insofar as wild and selective breeding has produced variations which include up to 6 sets of chromosomes (3x the human genome worth!) capable of generating a massive number of proteins each with a distinct potentiality for antigenicity.
Common bread wheat (Triticum aestivum), for instance, has over 23,788 proteins cataloged thus far. In fact, the genome for common bread wheat is actually 6.5 times larger than that of the human genome!
With up to a 50% increase in gluten content of some varieties of wheat, it is amazing that we continue to consider “glue-eating” a normal behavior, whereas wheat-avoidance is left to the “celiac” who is still perceived by the majority of health care practitioners as mounting a “freak” reaction to the consumption of something intrinsically wholesome.
Thankfully we don’t need to rely on our intuition, or even (not so) common sense to draw conclusions about the inherently unhealthy nature of wheat.
A wide range of investigation has occurred over the past decade revealing the problem with the alcohol soluble protein component of wheat known as,
...found in wheat.
Add to these the anti-nutrients found in grains such as phytates, enzyme inhibitors, etc. and you have a substance which we may more appropriately consider the farthest thing from wholesome.
The remainder of this article will demonstrate the following adverse effects of wheat on both celiac and non-celiac populations:
CONCLUSION
In this article I have proposed that celiac disease be viewed not as a rare “genetically-determined” disorder, but as an extreme example of our body communicating to us a once universal, species-specific affliction: severe intolerance to wheat.
Celiac disease reflects back to us how profoundly our diet has diverged from what was, until only recently a grain free diet, and even more recently, a wheat free one. We are so profoundly distanced from that dramatic Neolithic transition in cultural time that,
The body, on the other hand, cannot help but remember a time when cereal grains were alien to the diet, because in biological time it was only moments ago.
Eliminating wheat, if not all of the members of the cereal grass family, and returning to dicotyledons or pseudo-grains like quinoa, buckwheat and amaranth, may help us roll back the hands of biological and cultural time, to a time of clarity, health and vitality that many of us have never known before.
When one eliminates wheat and fills the void left by its absence with fruits, vegetables, high quality meats and foods consistent with our biological needs we may begin to feel a sense of vitality that many would find hard to imagine.
If wheat really is more like a drug than a food, anesthetizing us to its ill effects on our body, it will be difficult for us to understand its grasp upon us unless and until we eliminate it from our diet. I encourage everyone to see celiac disease not as a condition alien to our own. Rather, the celiac gives us a glimpse of how profoundly wheat may distort and disfigure our health if we continue to expose ourselves to its ill effects.
I hope this article will provide inspiration for non-celiacs to try a wheat free diet and judge for themselves if it is really worth eliminating.
REFERENCES
Opening Pandora's Bread Box The Critical Role of Wheat Lectin in Human Disease March 24, 2010
Now that celiac disease has been allowed official entry into the pantheon of established medical conditions, and gluten intolerance is no longer entirely a fringe medical concept, the time has come to draw attention to the powerful little chemical in wheat known as 'wheat germ agglutinin' (WGA) which is largely responsible for many of wheat's pervasive, and difficult to diagnose, ill effects.
Not only does WGA throw a monkey wrench into our assumptions about the primary causes of wheat intolerance, but due to the fact that WGA is found in highest concentrations in "whole wheat," including its supposedly superior sprouted form, it also pulls the rug out from under one of the health food industry's favorite poster children.
Below the radar of conventional serological testing for antibodies against the various gluten proteins and genetic testing for disease susceptibility, the WGA “lectin problem” remains almost entirely obscured.
Lectins, though found in all grains, seeds, legumes, dairy and our beloved nightshades: the tomato and potato, are rarely discussed in connection with health or illness, even when their presence in our diet may greatly reduce both the quality and length of our lives.
Although significant progress has been made in exposing the dark side of wheat over the past decade, gluten receives a disproportionate share of the attention.
Given that modern bread wheat (Triticum Aestivum) is a hexaploid species containing six distinct sets of chromosomes capable of producing well over 23,000 unique proteins, it is not surprising that we are only now beginning to unravel the complexities of this plant’s many secrets. [1]
What is unique about WGA is that it can do direct damage to the majority of tissues in the human body without requiring a specific set of genetic susceptibilities and/or immune-mediated articulations. This may explain why chronic inflammatory and degenerative conditions are endemic to wheat-consuming populations even when overt allergies or intolerances to wheat gluten appear exceedingly rare.
The future fate of wheat consumption, and by implication our health, may depend largely on whether or not the toxic qualities of WGA come to light in the general population.
Nature engineers, within all species, a set of defenses against predation, though not all are as obvious as the thorns on a rose or the horns on a rhinoceros.
Plants do not have the cell-mediated immunity of higher life forms, like ants, nor do they have the antibody driven, secondary immune systems of vertebrates with jaws. They must rely on a much simpler, innate immunity. It is for this reason that seeds of the grass family, e.g. rice, wheat, spelt, rye, have exceptionally high levels of defensive glycoproteins known as lectins, which function much like "invisible thorns."
Cooking, sprouting, fermentation and digestion are the traditional ways in which man, for instance, deals with the various anti-nutrients found within this family of plants, but lectins are, by design, particularly resistant to degradation through a wide range of pH and temperatures.
WGA lectin is an exceptionally tough adversary as it is formed by the same disulfide bonds that make vulcanized rubber and human hair so strong, flexible and durable.
Like man-made pesticides, lectins are extremely small, resistant to break-down by living systems, and tend to accumulate and become incorporated into tissues where they interfere with normal biological processes. Indeed, WGA lectin is so powerful as an insecticide that biotech firms have used recombinant DNA technology to create genetically modified WGA-enhanced plants.
We can only hope that these virtually unregulated biotech companies, who are in the business of playing God with the genetic infrastructure of Life, will realize the potential harm to humans that such genetic modifications can cause.
Lectins are sugar-binding proteins, and through thousands of years of selectively breeding wheat for increasingly larger quantities of protein, the concentration of WGA lectin has increased proportionately. This, no doubt, has contributed to wheat’s global dominance as one of the world’s favored monocultures, offering additional “built-in” pest resistance.
The word lectin comes from the same etymological root as the word select, and literally means "to choose."
Lectins are designed "to choose" specific carbohydrates that project off the surface of cells and upon which they attach. In the case of WGA the two glycoproteins it selects for, in order of greatest affinity, are N-Acetyl Glucosamine and N-Acetylneuraminic acid (sialic acid).
WGA is Nature's ingenious solution for protecting the wheat plant from the entire gamut of its natural enemies.
Fungi have cell walls composed of a polymer of N-Acetylglucosamine. The cellular walls of bacteria are made from a layered structure called the peptidoglycan, a biopolymer of N-Acetylglucosamine. N-acetylglucosamine is the basic unit of the biopolymer chitin, which forms the outer coverings of insects and crustaceans (shrimp, crab, etc.).
All animals, including worms, fish, birds and humans, use N-Acetyglucosamine as a foundational substance for building the various tissues in their bodies, including the bones.
The production of cartilage, tendons, and joints depend on the structural integrity of N-Acetylglucosamine. The mucous known as the glycocalyx, or literally, “sugar coat” is secreted in humans by the epithelial cells which line all the mucous membranes, from nasal cavities to the top to the bottom of the alimentary tube, as well as the protective and slippery lining of our blood vessels.
The glycocalyx is composed largely of N-Acetylglucosamine and N-Acetylneuraminic acid (also known as sialic acid), with carbohydrate end of N-Acetylneuraminic acid of this protective glycoprotein forming the terminal sugar that is exposed to the contents of both the gut and the arterial lumen (opening).
WGA's unique binding specificity to these exact two glycoproteins is not accidental. Nature has designed WGA perfectly to attach to, disrupt, and gain entry through these mucosal surfaces.
It may strike some readers as highly suspect that wheat - the “staff of life” - which has garnered a reputation for “wholesome goodness” the world over, could contain a powerful health-disrupting anti-nutrient, which is only now coming to public attention.
WGA has been overshadowed by the other proteins in wheat. Humans - not Nature - have spent thousands of years cultivating and selecting for larger and larger quantities of these proteins. These pharmacologically active, opiate-like proteins in gluten are known as gluten exorphins (A5, B4, B5, C) and gliadorphins.
They may effectively anesthetize us, in the short term, to the long term, adverse effects of WGA. Gluten also contains exceptionally high levels of the excitotoxic l-aspartic and l-glutamic amino acids, which can also be highly addictive, not unlike their synthetic shadow molecules aspartame and monosodium glutamate.
In a previous article on the topic, New Perspectives on Celiac Disease and Wheat Intolerance,[2] we explored the role that these psychotropic qualities in grains played in ushering in civilization at the advent of the Neolithic transition 10,000 BC.
No doubt the narcotic properties of wheat are the primary reason why suspicions about its toxicity have remained merely speculation for thousands upon thousands of years.
WGA is most concentrated in the seed of the wheat plant, likely due to the fact that the seeds are the “babies” of these plants and are invested with the entire hope for continuance of their species. Protecting the seed against predation is necessarily a first priority. WGA is an exceedingly small glycoprotein (36 kilodaltons) and is concentrated deep within the embryo of the wheat berry (approximately 1 microgram per grain).
WGA migrates during germination to the roots and tips of leaves, as the developing plant begins to project itself into the world and outside the safety of its seed. In its quest for nourishment from the soil, its roots are challenged with fungi and bacteria that seek to invade the plant. In its quest for sunlight and other nourishment from the heavens the plant’s leaves become prey to insects, birds, mammals, etc.
Even after the plant has developed beyond the germination and sprouting stages it contains almost 50% of the levels of lectin found in the dry seeds. Approximately one third of this WGA is in the roots and two thirds is in the shoot, for at least 34 days. [3]
Each grain contains about 1 microgram of WGA. That seems hardly enough to do any harm to animals our size.
Lectins, however, are notoriously dangerous even in minute doses and can be fatal when inhaled or injected directly into the bloodstream. According to the U.S. Centers for Disease Control it takes only 500 micrograms (about half a grain of sand) of ricin (a lectin extracted from castor bean casings) to kill a human.
A single, one ounce slice of wheat bread contains approximately 500 micrograms of WGA, which if it were refined to its pure form and injected directly into the blood, could, in theory, have platelet aggregating and erythrocyte agglutinizing effects strong enough to create an obstructive clot such as occurs in myocardial infarction and stroke.
This, however, is not a likely route of exposure and in reality the immediate pathologies associated with lectins like ricin and WGA are largely restricted to the gastrointestinal tract where they cause mucosal injuries.
The point is that WGA, even in small quantities, could have profoundly adverse effects, given suitable conditions. Ironically, WGA is exceptionally small, at 36 kilodaltons (approximately the mass of 36,000 hydrogen atoms) and it can pass through the cell membranes of the intestine with ease.
The intestines will allow passage of molecules up to 1,000 kilodaltons in size. Moreover, one wheat kernel contains 16.7 trillion individual molecules of WGA, with each molecule of WGA having four N-Acetylglucosamine binding sites.
The disruptive and damaging effects of whole wheat bread consumption are formidable in someone whose protective mucosal barrier has been compromised by something as simple as Non-Steroidal Anti-Inflammatory Drug (NSAID) use, or a recent viral or bacterial infection. The common consumption of both wheat and NSAIDs may suggest the frequency of the WGA vicious cycle.
Anti-inflammatory medications, such as ibuprofen and aspirin, increase intestinal permeabilty and may cause absorption of even larger than normal quantities of pro-inflammatory WGA.
Conversely, the inflammation caused by the absorption of WGA lectin is the very reason there is a great need for the inflammation-reducing effects of NSAIDs.
One way to gauge just how pervasive the adverse effects of WGA are among wheat-consuming populations is the popularity of the dietary supplement glucosamine. In the USA, a quarterbillion dollars’ worth of the glucosamine is sold annually.
The main source of glucosamine on the market is from the N-Acetylglucosamine rich chitin exoskelotons of crustaceans, like shrimp and crab. Glucosamine is used for reducing pain and inflammation.
We do not have a dietary deficiency of the pulverized shells of dead sea critters, just as our use of NSAIDs is not caused by a deficiency of these synthetic chemicals in our diet.
When we consume glucosamine supplements, the WGA, instead of binding to our tissues, binds to the pulverized chitin in the glucosamine supplements, sparing us from the full impact of WGA. Many millions of Americans who have greatly reduced their pain and suffering by ingesting glucosamine and NSAIDs may be better served by removing wheat, the underlying cause of their malaise, from their diets.
This would result in even greater relief from pain and inflammation along with far less dependency on palliative supplements and medicines alike.
To further underscore this point, the following are several ways that WGA depletes our health while glucosamine works against it:
Given the multitude of ways in which WGA may disrupt our health, gain easy entry through our intestine into systemic circulation, and remain refractory to traditional antibody-based clinical diagnoses, it is altogether possible that the consumption of wheat is detracting from the general health of the wheat-consuming world and that we have been, for all these years,
This perspective may come as a great surprise to the health food industry whose particular love affair for whole wheat products has begun to go mass market.
The increasingly hyped-up marketing of "whole wheat," "sprouted grain," and "wheat germ" enriched products, all of which may have considerably higher levels of WGA than their processed, fractionized, non-germinated and supposedly "less healthy" equivalents, may contribute to making us all significantly less healthy.
It is my belief that a careful study of the wheat plant will reveal that, despite claims to the contrary, man does not have dominion over nature. All that he deems fit for his consumption may not be his inborn right.
Though the wheat plant’s apparently defenseless disposition would seem to make it suitable for mass human consumption, it has been imbued with a multitude of invisible “thorns,” with WGA being its smallest and perhaps most potent defense against predation. While WGA may be an uninvited guest at our table, wheat is equally inhospitable to us.
Perhaps the courteous thing to do, having realized our mistaken intrusion, is to lick our wounds and simply go our separate ways.
Perhaps as the distance between man and his infatuation with wheat grows, he will grow closer to himself and will discover far more suitable forms of nourishment that Nature has not impregnated with such high levels of addictive and potentially debilitating proteins.
REFERENCES
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