Gene therapy via skin could treat many diseases, even obesity!

Using CRISPR and skin grafts, researchers boost insulin levels to reduce weight - from August 3rd 2017

Credit - https://www.sciencedaily.com/releases/2017/08/170803122728.htm

University of Chicago Medical Center

Scientist have now overcome challenges that have limited the use of gene therapy. They
demonstrate how their novel approach with skin transplantation could enable a wide range of gene based
therapies to treat human diseases. The researchers provide 'proof-of-concept,' treating mice
with two common related human ailments: type-2 diabetes and obesity.

When normal and gene-altered mice ate the high-fat diet --
along with varying levels of doxycycline to induce GLP1 release
mice expressing GLP1 (left) gained less weight gain while normal mice (right) grew fat.

In the August 3, 2017 issue of the journal Cell Stem Cell, the researchers provide "proof-of-concept." They
describe a new form of gene-therapy -- administered through skin transplants -- to treat two related and extremely
common human ailments: type-2 diabetes and obesity.

"We resolved some technical hurdles and designed a mouse-to-mouse skin transplantation model in animals with
intact immune systems," said study author Xiaoyang Wu, PhD, assistant professor in the Ben May Department for
Cancer Research at the University of Chicago. "We think this platform has the potential to lead to safe and durable
8/7/2017 Gene therapy via skin could treat many diseases, even obesity: Using CRISPR and skin grafts, researchers boost insulin levels to reduce weight …

gene therapy, in mice and we hope, someday, in humans, using selected and modified cells from skin."
Beginning in the 1970s, physicians learned how to harvest skin stem cells from a patient with extensive burn
wounds, grow them in the laboratory, then apply the lab-grown tissue to close and protect a patient's wounds. This
approach is now standard. However, the application of skin transplants is better developed in humans than in
mice.

"The mouse system is less mature," Wu said. "It took us a few years to optimize our 3D skin organoid culture
system."

This study, "Engineered epidermal progenitor cells can correct diet-induced obesity and diabetes," is the first to
show that an engineered skin graft can survive long term in wild-type mice with intact immune systems. "We have
a better than 80 percent success rate with skin transplantation," Wu said. "This is exciting for us."
They focused on diabetes because it is a common non-skin disease that can be treated by the strategic delivery of
specific proteins.

The researchers inserted the gene for glucagon-like peptide 1 (GLP1), a hormone that stimulates the pancreas to
secrete insulin. This extra insulin removes excessive glucose from the bloodstream, preventing the complications
of diabetes. GLP1 can also delay gastric emptying and reduce appetite.
Using CRISPR, a tool for precise genetic engineering, they modified the GLP1 gene. They inserted one mutation,
designed to extend the hormone's half-life in the blood stream, and fused the modified gene to an antibody
fragment so that it would circulate in the blood stream longer. They also attached an inducible promoter, which
enabled them to turn on the gene to make more GLP1, as needed, by exposing it to the antibiotic doxycycline.
Then they inserted the gene into skin cells and grew those cells in culture.

When these cultured cells were exposed to an air/liquid interface in the laboratory, they stratified, generating what
the authors referred to as a multi-layered, "skin-like organoid." Next, they grafted this lab-grown gene-altered skin
onto mice with intact immune systems. There was no significant rejection of the transplanted skin grafts.
When the mice ate food containing minute amounts of doxycycline, they mice released dose-dependent levels of
GLP1 into the blood. This promptly increased blood-insulin levels and reduced blood-glucose levels.
When the researchers fed normal or gene-altered mice a high-fat diet, both groups rapidly gained weight. They
became obese. When normal and gene-altered mice got the high-fat diet along with varying levels of doxycycline,
to induce GLP1 release, the normal mice grew fat and mice expressing GLP1 showed less weight gain.
Expression of GLP1 also lowered glucose levels and reduced insulin resistance.

"Together, our data strongly suggest that cutaneous gene therapy with inducible expression of GLP1 can be used
for the treatment and prevention of diet-induced obesity and pathologies," the authors wrote. When they
transplanted gene-altered human cells to mice with a limited immune system, they saw the same effect. These
results, the authors wrote, suggest that "cutaneous gene therapy for GLP1 secretion could be practical and
clinically relevant."

This approach, combining precise genome editing in vitro with effective application of engineered cells in vivo,
could provide "significant benefits for the treatment of many human diseases," the authors note.
"We think this can provide a long-term safe option for the treatment of many diseases," Wu said. "It could be used
to deliver therapeutic proteins, replacing missing proteins for people with a genetic defect, such as hemophilia. Or
it could function as a metabolic sink, removing various toxins."