This confocal microscopic image shows a
two-month-old human esophageal organoid bioengineered by scientists from
pluripotent stem cells. About 700 micrometers (0.027 inches) in size,
the organoid is stained to visualize key structural proteins expressed
in mature esophagus, such as involucrin (green) and cornulin (blue).
Researchers report in the journal Cell Stem Cell the organoids enhance
the study of esophageal disorders, personalized medical and the
development of regenerative tissue therapies for people.
Credit: Cincinnati Children's
Scientists working to bioengineer the entire
human gastrointestinal system in a laboratory now report using
pluripotent stem cells to grow human esophageal organoids.
Published in the journal Cell Stem Cell the study is the
latest advancement from researchers at the Cincinnati Children's Center
for Stem Cell and Organoid Medicine (CuSTOM). The center is developing
new ways to study birth defects and diseases that affect millions of
people with gastrointestinal disorders, such as gastric reflux, cancer,
etc. The work is leading to new personalized diagnostic methods and
focused in part on developing regenerative tissue therapies to treat or
cure GI disorders.
The newly published research is the first time scientists have been
able to grow human esophageal tissue entirely from pluripotent stem
cells (PSCs), which can form any tissue type in the body, according to
the authors. Cincinnati Children's scientists and their
multi-institutional collaborators already have used PSCs to bioengineer
human intestine, stomach, colon and liver.
"Disorders of the esophagus and trachea are prevalent enough in
people that organoid models of human esophagus could be greatly
beneficial," said Jim Wells, PhD, chief scientific officer at CuSTOM and
study lead investigator. "In addition to being a new model to study
birth defects like esophageal atresia, the organoids can be used to
study diseases like eosinophilic esophagitis and Barrett's metaplasia,
or to bioengineer genetically matched esophageal tissue for individual
patients."
The study involves collaboration from researchers in the divisions of
Developmental Biology, Oncology, Allergy and Immunology, and
Endocrinology at Cincinnati Children's and the Gladstone Institutes in
San Francisco. This includes study first author Stephen Trisno, a
graduate student and member of the Wells laboratory.
The Food Channel
The esophagus is a muscular tube that actively passes food from the
mouth to the stomach. The organ can be affected by congenital diseases,
such as esophageal atresia -- a narrowing or malformation of the
esophagus caused by genetic mutations.
Additionally, there are several diseases that can afflict people
later in life. Some include esophageal cancer, gastroesophageal reflux
disease (GERD), or a rare ailment called achalasia -- a disease
affecting the muscles of the lower esophagus that prevents contraction
of the organ and the passage of food.
All of the conditions need better treatments, researchers note. This
requires a more precise understanding of the genetic and biochemical
mechanisms behind their cause -- a need filled by the ability to
generate and study robust, functional, genetically matched models of
human esophageal tissue that can be grown from a person's own cells.
Tracing Nature's Path
The scientists based their new method for using human PSCs to general
esophageal organoids on precisely timed, step-by-step manipulations of
genetic and biochemical signals that pattern and form embryonic endoderm
and foregut tissues. They focused in part on the gene Sox2 and its
associated protein -- which are already known to trigger esophageal
conditions when their function is disrupted. -- The scientists used
mice, frogs and human tissue cultures to identify other genes and
molecular pathways regulated by Sox2 during esophagus formation.
The scientists report that during critical stages of embryonic
development, the Sox2 gene blocks the programming and action of genetic
pathways that direct cells to become respiratory instead of esophageal.
In particular, the Sox2 protein inhibits the signaling of a molecule
called Wnt and promotes the formation and survival of esophageal
tissues.
In another test to help confirm the importance of Sox2 expression on
esophageal formation, researchers studied the complete loss of Sox2
during the development process in mice. The absence of Sox2 resulted in
esophageal agenesis -- a condition in which the esophagus terminates in a
pouch and does not connect to the stomach.
After successfully generating fully formed human esophageal organoids
-- which grew to a length of about 300-800 micrometers in about two
months -- the bioengineered tissues were compared biochemically to
esophageal tissues from patient biopsies. Those tests showed the
bioengineered and biopsies tissues were strikingly similar in
composition, according to the authors.
The research team is continuing its studies into the bioengineering
process for esophageal organoids and identifying future projects to
advance the technology's eventual therapeutic potential, according to
Wells. This includes using the organoids to examine the progression of
specific diseases and congenital defects affecting the esophagus.
Journal Reference:
- Stephen L. Trisno, Katherine E.D. Philo, Kyle W. McCracken, Emily M. Catá, Sonya Ruiz-Torres, Scott A. Rankin, Lu Han, Talia Nasr, Praneet Chaturvedi, Marc E. Rothenberg, Mohammad A. Mandegar, Susanne I. Wells, Aaron M. Zorn, James M. Wells. Esophageal Organoids from Human Pluripotent Stem Cells Delineate Sox2 Functions during Esophageal Specification. Cell Stem Cell, 2018; DOI: 10.1016/j.stem.2018.08.008
Courtesy: ScienceDaily
