50 Shades of Gluten (Intolerance)
by Chris Kresser, Huffington Post
Celiac disease (CD) was initially described in the first century A.D. by a Greek physician named Aretaeus of Cappadocia. But neither Aretaeus nor anyone else knew that CD is caused by an autoimmune reaction to gluten, a protein in wheat. That didn't become clear until 1950 -- several centuries later -- when Dr. Willem Dicke, a Dutch pediatrician, conclusively proved that gluten was the culprit. Dicke's discovery saved millions of children and adults from the perils of untreated celiac disease, including malnutrition, stunted growth, cancer, severe neurological and psychiatric illness and even death.
Since then, the mainstream view of gluten intolerance has been relatively black or white: Either you have celiac disease, in which case even a small amount of gluten will send you running to the bathroom in three seconds flat, or you don't, and you can chug down beer and bagels without fear. This "all-or-nothing" view has led to some doctors telling patients that suspect they're sensitive to gluten but test negative for CD that they're simply imagining an affliction that doesn't exist.
It turns out those doctors are wrong.
The Many Shades of Gluten Intolerance
In order to explain why, I have to give you a quick lesson in the biochemistry of wheat and wheat digestion.
Wheat contains several different classes of proteins. Gliadins and glutenins are the two main components of the gluten fraction of the wheat seed. (They're essential for giving bread the ability to rise properly during baking.) Within the gliadin class, there are four different epitopes (i.e. types): alpha-, beta-, gamma- and omega-gliadin. Wheat also contains agglutinins (proteins that bind to sugar) and prodynorphins (proteins involved with cellular communication). Once wheat is consumed, enzymes in the digestive tract called tissue transglutaminases (tTG) help to break down the wheat compound. In this process, additional proteins are formed, including deamidated gliadin and gliadorphins (aka gluteomorphins).
Here's the crucial thing to understand: Celiac disease is characterized by an immune response to a specific epitope of gliadin (alpha-gliadin) and a specific type of transglutaminase (tTG-2). But we now know that people can (and do) react to several other components of wheat and gluten -- including other epitopes of gliadin (beta, gamma, omega), glutenin, WGA and deamidated gliadin -- as well as other types of transglutaminase, including type 3 (primarily found in the skin) and type 6 (primarily found in the brain).
This is a huge problem because conventional lab testing for CD and of gluten intolerance only screens for antibodies to alpha-gliadin and transglutaminase-2. If you're reacting to any other fractions of the wheat protein (e.g., beta-gliadin, gamma-gliadin or omega-gliadin), or any other types of transglutaminase (e.g., type 3 or type 6), you'll test negative for CD and gluten intolerance no matter how severely you're reacting to wheat.
Beyond Celiac: Why CD Is Just the Tip of the Iceberg
Official statistics suggest that Celiac disease affects between 0.7 percent and 1 percent of the U.S. population. But considering the limited scope of the testing, it's possible that the actual incidence might be much higher.
In addition, CD is only the tip of the iceberg when it comes to gluten intolerance. Celiac disease is caused by a distinct autoimmune response to wheat proteins and transglutaminase enzymes in the gut. But CD is just one possible expression of gluten intolerance; there are many other ways that sensitivity to gluten can manifest in the body. These are collectively referred to as "Non-Celiac Gluten Sensitivity," or NCGS.
There's no consensus definition of NCGS yet, but the most common understanding is that it's a reaction to gluten that is not autoimmune (like CD) or allergic (like wheat allergy). Another definition I've seen is, "a reaction to gluten that resolves when gluten is removed from the diet and CD and allergy have been ruled out."
It's difficult to estimate the prevalence of NCGS because there is no definitive diagnostic test for it. As I mentioned above, the currently available tests for gluten sensitivity are primitive and only screen for a small fraction of the components of wheat that people react to. Another issue is the variety of symptoms caused by CD and NCGS. While most people assume that gluten intolerance always causes digestive distress, this is not the case. Almost 50 percent of new patients diagnosed with CD do not have gastrointestinal symptoms. Moreover, for every one case of CD that is diagnosed, there are 6.4 cases that remain undiagnosed -- the majority of which are atypical or silent forms without gastrointestinal symptoms.
Gluten intolerance can affect nearly every tissue in the body, including the brain, skin, endocrine system, stomach, liver, blood vessels, smooth muscles and even the nucleus of cells. CD and NCGS are associated with an astonishing variety of diseases, from schizophrenia and epilepsy, to Type 1 diabetes and osteoporosis, to dermatitis and psoriasis, to Hashimoto's hypothyroidism to peripheral neuropathy. Because the range of symptoms associated with gluten intolerance is so broad and nonspecific (e.g., can be attributed to any number of conditions), many patients and doctors don't suspect gluten may be the cause.
Even with these limitations, some estimates suggest NCGS may occur in as many as 1 in 20 Americans. And while some mainstream medical professionals continue to insist that NCGS doesn't exist, several studies have validated it as a distinct clinical condition -- including gold-standard, double-blind, placebo-controlled trials.
The Gluten-Free Challenge: Still the Best Test for Gluten Intolerance
With all of this in mind, the obvious question that arises is, "What's the best way to test for gluten intolerance?" Because of the limitations of current laboratory testing I described above, most experts on gluten sensitivity agree that the only reliable test is a "gluten challenge." This involves removing gluten from the diet completely for a period of at least 30 days, and then adding it back in after that. If symptoms improve during the elimination period, and return when gluten is reintroduced, a diagnosis of NCGS can be made.
However, for many people a gluten-free diet isn't enough. Some grains that don't contain gluten, such as corn, oats and rice, contain proteins that are similar enough in structure to gluten to elicit an immune response in people with CD or NCGS. In addition, about 50 percent of patients with CD show signs of intolerance to casein, the protein in milk. This may explain why up to 30 percent of CD patients continue to have symptoms or clinical signs after adopting a gluten-free diet. For this reason, I recommend a completely grain- and dairy-free diet during the gluten challenge period. (A Paleo diet is an excellent choice. Visit my website to learn more.)
Finally, though the gluten challenge is still the gold standard test for gluten intolerance, there is a relatively new lab (Cyrex Laboratories) offering a comprehensive blood test which screens for all of the wheat and gluten proteins and transglutaminase enzymes I mentioned above. This can be a helpful diagnostic tool, but it should never replace a gluten/Paleo challenge. (Note: It must be ordered by a physician or health care practitioner.)
Now I'd like to hear from you. Do you suspect you may have gluten intolerance? If so, has removing gluten resolved your symptoms -- or have you found it necessary to remove grains and dairy as well? If you haven't tried a gluten challenge, what's holding you back?