Contact:
Donna Krupa
Office: (301) 634-7209
Cell: (301) 332-4402
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Celiac Success: New Enzyme
Efficiently Degrades Gluten
Food grade enzyme works
fast in stomach environment
End of the gluten-free diet
in sight?
BETHESDA, MD (June 30, 2006) – A new enzyme originally
developed for commercial food processing turns out to also quickly and
nearly-completely break down whole gluten molecules as well as the T cell
stimulatory peptides that cause celiac disease, a digestive disease with no
current effective treatment other than avoiding wheat, barley or
rye products.
In addition, the enzyme operates best in just the kind
of physiological environment found in the human stomach and works 60 times
faster than an earlier promising enzyme, which was not effective in acidic
conditions and was inactivated by pepsin, both of which are found in the
stomach.
“On the basis of our results, there now is a realistic
chance that oral supplementation with an enzyme can ensure gluten
degradation in the stomach before reaching the small intestine, where it
causes problems for people with celiac disease,” according to Frits Koning,
researcher at the Leiden University Medical Center, The Netherlands, who
headed the team that has published a new research paper on its work.
The paper, “Highly efficient gluten degradation with a
newly identified prolyl endoprotease: implications for celiac disease,” is
in the online American Journal of Physiology- Gastrointestinal and Liver
Physiology, published by The American Physiological Society.
Research was by Dariusz Stepniak, Liesbeth Spaenij-Dekking, Cristina Mitea,
Martine Moester, Arnoud de Ru, Renee Baak-Pablo, Peter van Veelen and Frits
Koning of Leiden University Medical Center, the Netherlands, and Luppo Edens
of DSM Food Specialties, Delft.
Clinical trials are likely next step
The new prolyl endoprotease (PEP) that was studied is
derived from Aspergillus niger (AN), a common fungus. Strains of
A. niger are used in industrial production of citric and gluconic acid
as well as producing several food grade enzymes.
Because there are no animal models of celiac disease,
“the in vivo efficacy of AN-PEP for gluten detoxification will ultimately
have to be addressed in clinical studies involving celiac patients. AN-PEP
appears to be a prime candidate for such clinical trials,” the paper
concluded. As for the timing of any such trials, Koning said: “This is an
option the team hopes to explore in the future.”
A disease of many paradoxes
Celiac disease affects about 2 million Americans and is
also found in Europe, India and parts of the Middle East. It’s caused by an
uncontrolled immune response to wheat gluten and similar proteins of rye and
barley that cause diarrhea, malnutrition and failure to thrive because it
inhibits nutritional uptake.
“It’s a Caucasian disease with a wide spectrum of
symptoms; not all patients are equally affected, but we do not understand
why this is the case,” Koning said. “It is known to be associated with the
HLA-DQ2 gene,” he noted, “but while about 25% of the white population has
this gene, only about one in 100 get the disease, so it’s really a quite
puzzling disease in many ways.”
Currently the only way to elude the disease symptoms is
by avoiding wheat, barley and rye products. “It sounds easy, but gluten
especially is widespread in Western diets,” Koning said. Gluten is often
used as a food additive because it adds protein content inexpensively and
also gives dough its elasticity and stickiness, which helps in
manufacturing. For instance, Koning said: “Celiac patients can eat potato
chips, but not if they have added paprika or other spices because they’re
‘glued’ to the chip with gluten.”
AN-PEP outstrips earlier enzyme by 60-fold
Earlier attempts at finding non-human proteases for
gluten detoxification (first proposed in the late 1950s) focused on prolyl
oligopeptidases (POP), most notably FM-POP, which was able to break down
gluten sequences in vitro. However FM-POP’s optimal operating pH is between
7 and 8, so it didn’t work well in the more acidic stomach pH that goes down
to 2 at one stage. A combination of pH 2 and pepsin “immediately inactivated
FM-POP,” the paper said. AN-PEP, on the other hand, is active from pH 2-8,
with optimum effect around pH 4. The combination of pH 2 and pepsin didn’t
affect AN-PEP activity.
“An effective enzymatic treatment for celiac diseases
requires means of destroying all or at least the vast majority of gluten
derived T cell stimulatory sequences,” the paper said. The key to this is to
break the large gluten molecules (large peptides and intact proteins) into
smaller pieces before they leave the stomach. Because food stays in the
stomach one to four hours, speed of protein degradation is also important.
Mass spectrometry comparisons showed that “degradation of gluten peptides by
AN-PEP was on average [about 4 minutes, or] 60 times faster than degradation
by FM-POP,” the paper reported.
In addition to its ability to perform as a potential
oral enzymatic therapy because it “is capable of degrading intact gluten
molecules and T cell stimulatory epitopes from gluten into harmless
fragments” AN-PEP has several additional commercial advantages, the paper
said: “The enzyme is extremely stable and can be produced at acceptable cost
at food grade quality in an industry setting.”
Celiac disease is an HLA-linked disease related to Type
1 diabetes and rheumatoid arthritis in which autoimmune reactions cause the
disease; similarly, immune reactions can lead to organ transplant rejection.
Koning said it “isn’t likely that AN-PEP would be of any therapeutic value
in any of these HLA-associated diseases” because Type 1 diabetes and
rheumatoid arthritis are real autoimmune diseases, where the immune system
attacks parts of the body. In celiac disease, it is the gluten that is the
target, not the body.
Reminder warning on early introduction of gluten
products
Koning said feeding wheat (or barley or rye) products
to infants before they’re 6 months old isn’t recommended because once an
immune response develops “immuno-memory builds up and it doesn’t go away.”
Indeed, Koning noted that in Sweden some years ago gluten was introduced
into baby food, which led to a five-fold increase in celiac disease. The
problem disappeared when gluten was removed.
Source and funding/support
The paper, “Highly efficient gluten degradation with a
newly identified prolyl endoprotease: implications for celiac disease,” is
in the online American Journal of Physiology-Gastrointestinal and Liver
Physiology, published by The American Physiological Society.
Research was by Dariusz Stepniak, Liesbeth Spaenij-Dekking, Cristina Mitea,
Martine Moester, Arnoud de Ru, Renee Baak-Pablo, Peter van Veelen and Frits
Koning, Department of Immunohematology and Blood Transfusion, Leiden
University Medical Center, Leiden, the Netherlands, and Luppo Edens of DSM
Food Specialties, Delft, a subsidiary of
Koninklijke DSM N.V., a Dutch chemical conglomerate.
Research supported by Netherlands Organization for
Scientific Research, Celiac Disease Consortium, Centre for
Medical Systems Biology (the latter two partly backed by the
Netherlands Genomics Initiative). DSM supplied A. niger-derived
PEP (AN-PEP) on which it holds a patent.
Editor’s note: The media may obtain a copy of
Stepniak et al. by contacting Donna Krupa, American Physiological Society,
(301) 634-7209, cell (703) 967-2751 or
dkrupa@the-aps.org.
* * *
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