Islamabad, Jan 23 :
Researchers at Columbia University Medical Center (CUMC) have identified the
critical early cellular and molecular events that give rise to a type of
esophageal cancer called esophageal adenocarcinoma, the fastest-rising solid
tumor in the United States.
The findings, recently published in Cancer
Cell, challenge conventional wisdom regarding the origin and development of this
deadly cancer and its precursor lesion, Barrett's esophagus, and highlight
possible targets for new clinical therapies.
Lacking a good animal model
of esophageal adenocarcinoma (EAC), researchers have been hard pressed to
explain exactly where and how this cancer arises. What is known is that EAC is
usually triggered by gastroesophageal reflux disease (GERD), in which bile acid
and other stomach contents leak backwards from the stomach to the esophagus, the
muscular tube that moves food from the mouth to the stomach. Over time, acid
reflux can irritate and inflame the esophagus, leading to Barrett's esophagus,
an asymptomatic precancerous condition in which the tissue lining the esophagus
is replaced by tissue similar to the lining of the intestine. A small number of
people with Barrett's esophagus eventually go on to develop EAC.
Using a
new genetically engineered mouse model of esophagitis, the CUMC researchers have
clarified critical cellular and molecular changes that occur during the
development of Barrett's esophagus and EAC. In human patients, acid reflux often
leads to overexpression of a molecule called interleukin-1 beta, an important
mediator of the inflammatory response, reported study leader Timothy C. Wang,
MD, the Dorothy L. and Daniel H. Silberberg Professor of Medicine at CUMC. Thus,
Wang and his colleagues created a transgenic mouse in which interleukin-1 beta
was overexpressed in the esophagus.
Overexpression of interleukin-1 beta
in the mouse esophagus resulted in chronic esophageal inflammation (esophagitis)
and expansion of progenitor cells that were sustained by the notch signaling
pathway. Notch is a fundamental signaling system used by neighboring cells to
communicate with each other in order to assume their proper developmental role.
"When we inhibited notch signaling, that blocked proliferation and survival of
the pre-malignant cells, so that's a new possible clinical strategy to use in
Barrett's patients at high risk for cancer development," noted Dr.
Wang.
For decades, investigators thought that the physiological changes
associated with Barrett's esophagus originate in the lower esophagus. "However,
our study shows that Barrett's esophagus actually arises in the gastric cardia,
a small region between the lower part of the esophagus and the upper,
acid-secreting portion of the stomach," said Dr. Wang. "What happens is that the
bile acid and inflammatory cytokines activate stem cells at this transition
zone, and they begin migrating up toward the esophagus, where they take on this
intestinal-like appearance."
The researchers also demonstrated that these
changes occur primarily in columnar-like epithelial cells, rather than in goblet
cells, as was previously thought.
"All told, the findings present a new
model for the pathogenesis of Barrett's esophagus and esophageal
adenocarcinoma," said Dr. Wang.
Barrett's esophagus affects about 1
percent of adults in the United States. Men are affected by Barrett's esophagus
twice as frequently as women, and Caucasian men are affected more frequently
than men of other races. The average age at diagnosis is 50. At present, there
is no way to determine which patients with the condition will develop EAC. EAC
is increasing in incidence about 7 to 8 percent a year, making it the most
rapidly rising solid tumor in the U.S.
Treatment with acid-reducing drugs
can lessen symptoms of GERD and lower the chances of developing Barrett's
esophagus and EAC. Low-grade EAC is highly treatable with endoscopic
radiofrequency ablation, photodynamic therapy, or surgical resection. Patients
with severe disease may require open surgery, in which most of the esophagus is
removed. The overall five-year survival rate with advanced disease is about 25
percent.
Dr. Wang's paper is entitled, "Bile acid and inflammation
activate gastric cardia stem cells in a mouse model of Barrett's-like
metaplasia." The lead author is Michael Quante of CUMC and Technische
Universität München, Munich, Germany. The other contributors are Govind Bhagat,
Julian Abrams, Frederic Marache, Pamela Good, Michele D. Lee, Yoomi Lee, Richard
Friedman, Samuel Asfaha, MD, PhD, Zinaida Dubeykovskaya, Carrie Shawber, and
Charles Lightdale, all of CUMC; Umar Mahmood and Jose-Luiz Figueiredo, of
Harvard Medical School and Massachusetts General Hospital, Boston; Jan
Kitajewski of Technische Universität München; and Anil K Rustgi of the
University of Pennsylvania, Philadelphia.
Ends
SA/EN
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