Using CRISPR gene editing, a team from Children’s Hospital of Philadelphia (CHOP)and Penn Medicine have
thwarted a lethal lung disease in an animal model in which a harmful mutation
causes death within hours after birth. This proof-of-concept study, published
today in Science Translational Medicine, showed that in
utero editing could be a promising new approach for treating lung
diseases before birth.
“The developing fetus has many innate properties that make it an attractive
recipient for therapeutic gene editing,” said study co-leader William
H. Peranteau, MD, an investigator at CHOP’s Center for Fetal Research, and a pediatric and fetal
surgeon in CHOP’s Center for Fetal Diagnosis and Treatment. “Furthermore, the
ability to cure or mitigate a disease via gene editing in mid- to late
gestation before birth and the onset of irreversible pathology is very
exciting. This is particularly true for diseases that affect the lungs, whose
function becomes dramatically more important at the time of birth.”
The lung conditions the team is hoping to solve–congenital diseases such as
surfactant protein deficiency, cystic fibrosis, and alpha-1 antitrypsin–are
characterized by respiratory failure at birth or chronic lung disease with few
options for therapies. About 22 percent of all pediatric hospital admissions
are because of respiratory disorders, and congenital causes of respiratory
diseases are often lethal, despite advances in care and a deeper understanding
of their molecular causes. Because the lung is a barrier organ in direct
contact with the outside environment, targeted delivery to correct defective
genes is an attractive therapy.
“We wanted to know if this could work at all,” said study co-leader Edward
E. Morrisey, PhD, a professor of Cardiovascular Medicine in the Perelman School
of Medicine at the University of Pennsylvania. “The trick was how to direct the
gene-editing machinery to target cells that line the airways of the lungs.”
The researchers showed that precisely timed in utero delivery
of CRISPR gene-editing reagents to the amniotic fluid during fetal development
resulted in targeted changes in the lungs of mice. They introduced the gene
editors into developing mice four days before birth, which is analogous to the
third trimester in humans.
The cells that showed the highest percentage of editing were alveolar
epithelial cells and airway secretory cells lining lung airways. In 2018, a
team led by Morrisey identified the alveolar epithelial progenitor (AEP) lineage,
which is embedded in a larger population of cells called alveolar type 2 cells.
These cells generate pulmonary surfactant, which reduces surface tension in the
lungs and keeps them from collapsing with every breath. AEPs are a stable cell
type in the lung and turn over very slowly, but replicate rapidly after injury
to regenerate the lining of the alveoli and restore gas exchange.
In a second experiment, the researchers used prenatal gene-editing to
reduce the severity of an interstitial lung disease, surfactant protein C
(SFTPC) deficiency, in a mouse model that has a common disease-causing mutation
found in the human SFTPC gene. One hundred percent of untreated mice with this
mutation die from respiratory failure within hours of birth. In contrast,
prenatal gene editing to inactivate the mutant Sftpc gene resulted in improved
lung morphology and survival of over 22 percent of the animals.
Future studies will be directed towards increasing the efficiency of the
gene editing in the epithelial lining of lungs as well as evaluating different
mechanisms to deliver gene editing technology to lungs. “Different gene editing
techniques are also being explored that may one day be able to correct the
exact mutations observed in genetic lung diseases in infants,” Morrisey said.
Morrisey collaborated on a recent study led by Peranteau and Kiran
Musunuru, MD, PhD, an associate professor of Cardiovascular Medicine at
Penn, demonstrating the feasibility of in utero gene
editing to rescue a lethal metabolic liver disease in a mouse model –
the first time in utero CRISPR-mediated gene editing prevented
a lethal metabolic disorder in animals. Similar to that study, Peranteau says
“the current research is a proof-of-concept study highlighting the exciting
future prospects for prenatal treatments including gene editing and replacement
gene therapy for the treatment of congenital diseases.”
Journal article:
https://stm.sciencemag.org/content/11/488/eaav8375
https://stm.sciencemag.org/content/11/488/eaav8375
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