Moths and magnets deliver CRISPR to fix defective genes
A new therapy that relies on a moth-infecting virus and nanomagnets could repair genes that cause diseases like cystic fibrosis and sickle cell.
A new technology that relies on a moth-infecting virus and nanomagnets could edit defective genes that give rise to diseases like sickle cell, muscular dystrophy, and cystic fibrosis.
Researchers have combined magnetic nanoparticles with a viral container drawn from a particular species of moth to deliver CRISPR/Cas9 payloads that modify genes in a specific tissue or organ with spatial control.
Because magnetic fields are simple to manipulate and, unlike light, pass easily through tissue, researchers want to use them to control the expression of viral payloads in target tissues by activating the virus that is otherwise inactivated in blood.
In nature, CRISPR/Cas9 records the DNA of invaders to bolster microbes’ immune systems. That gives microbes the ability to recognize and attack returning invaders, but scientists have been racing to adapt CRISPR/Cas9 to repair mutations that cause genetic diseases and to manipulate DNA in laboratory experiments.
CRISPR/Cas9 has the potential to halt hereditary disease—if scientists can get the genome-editing machinery to the right cells inside the body. But roadblocks remain, especially in delivering the gene-editing payloads with high efficiency.
It will be necessary to edit cells in the body to treat many diseases, says Gang Bao, a bioengineer at Rice University.
“But efficiently delivering genome-editing machinery into target tissue in the body with spatial control remains a major challenge. Even if you inject the viral vector locally, it can leak to other tissues and organs, and that could be dangerous,” says Bao.
As reported in Nature Biomedical Engineering, the new delivery vehicle is based on a virus that infects Autographa californica, aka the alfalfa looper, a moth native to North America.
The cylindrical baculovirus vector (BV), the payload-carrying part of the virus, is considered large at up to 60 nanometers in diameter and 200-300 nanometers in length. That’s big enough to transport more than 38,000 base pairs of DNA, which is enough to supply multiple gene-editing units to a target cell, Bao says.
“We really didn’t know if this would work for gene editing or not, but we thought, ‘worth a shot.'”
The inspiration to combine BV and magnetic nanoparticles came from discussions with Rice postdoctoral researcher and co-lead author Haibao Zhu, who learned about the virus during a postdoctoral stint in Singapore but knew nothing about magnetic nanoparticles until he joined the Bao lab.
The team had previous experience using iron oxide nanoparticles and an applied magnetic field to open blood vessel walls just enough to let large-molecule drugs pass through.
“We really didn’t know if this would work for gene editing or not, but we thought, ‘worth a shot,'” Bao says.
The researchers use the magnetic nanoparticles to activate BV and deliver gene-editing payloads only where they’re needed. To do this, they take advantage of an immune-system protein called C3 that normally inactivates baculoviruses.
“If we combine BV with magnetic nanoparticles, we can overcome this deactivation by applying the magnetic field,” Bao says. “The beauty is that when we deliver it, gene editing occurs only at the tissue, or the part of the tissue, where we apply the magnetic field.”
Application of the magnetic field allows BV transduction, the payload-delivery process that introduces gene-editing cargo into the target cell. The payload is also DNA, which encodes both a reporter gene and the CRISPR/Cas9 system.
In tests, the BV was loaded with green fluorescent proteins or firefly luciferase. Cells with the protein glowed brightly under a microscope, and experiments showed the magnets were highly effective at targeted delivery of BV cargoes in both cell cultures and lab animals.
Bao notes his and other labs are working on the delivery of CRISPR/Cas9 with adeno-associated viruses (AAV), but he says BV’s capacity for therapeutic cargo is roughly eight times larger. “However, it is necessary to make BV transduction into target cells more efficient,” he says.
The National Institutes of Health and the Cancer Prevention and Research Institute of Texas supported the work.
Source: Rice University
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