Published online 1 March 2011 | Nature 471, 16 (2011) | doi:10.1038/471016a

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Targeted gene editing enters clinic

Patients with HIV first to receive experimental gene therapy.

A gene-therapy method that specifically disrupts a single gene may have had its first success in the clinic, potentially boosting immune-cell counts in a small number of patients with HIV. The results, presented on 28 February at the Conference on Retroviruses and Opportunistic Infections in Boston, Massachusetts, mark an important therapeutic test for enzymes known as zinc finger nucleases — small proteins that can be designed to bind to and edit specific DNA sequences by virtue of their zinc-bearing structures.

“If they did this several times in a given patient, you could establish a high percentage of resistant cells.”


The study, a phase I safety trial, tested a zinc finger enzyme developed by Sangamo BioSciences in Richmond, California. It included six men with HIV who were already taking the standard regimen of antiretroviral drugs. The drugs had kept the virus at bay, but their immune-cell counts remained abnormally low. Researchers removed a sample of CD4+ T cells, the type of immune cells affected by HIV, from each man and used Sangamo's enzyme to disrupt the CCR5 gene, which encodes a protein that HIV uses to enter CD4+ cells. The engineered cells were then infused back into the patients. Immune-cell counts subsequently rose for five of the six patients who received the therapy.

"It's very exciting," says John Rossi, a molecular biologist at the City of Hope's Beckman Research Institute in Duarte, California. "If they did this several times in a given patient, you could establish a high percentage of resistant cells."

The inspiration for targeting the CCR5 gene comes from the small percentage of people who, thanks to a natural mutation in the gene, are resistant to most types of HIV infection. At the meeting on Monday, Jacob Lalezari of Quest Clinical Research in San Francisco, California, reported that the engineered cells migrated throughout the body and thrived in the gut mucosa — a key reservoir of HIV. No serious side effects were seen.

The zinc finger nuclease technique is promising for the treatment of many diseases beyond HIV, says Patrick Aubourg, who studies gene therapy at France's national biomedical agency INSERM in Paris. The method could replace the more common technique of inserting modified genes into the genome, in which researchers have less control over the gene in question. But he cautions that the technique still has a relatively low efficiency and might have off-target effects.

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Meanwhile, Rossi, who is himself embarking on an HIV study that will use Sangamo's zinc finger nucleases, says that it is not yet clear whether the patients' CD4+ cell count rose because of the CCR5 disruption or because the extracted cells were activated as part of the protocol for growing them outside the body. And because levels of HIV were already below the threshold of detection in these patients, it is too early to say what effect the therapy could have on patients that have more of the virus. Researchers do not yet know what fraction of a person's CD4+ cells would need to be HIV-resistant to significantly rein in the virus's spread and liberate patients from a lifetime of antiretroviral drugs.

"It's going to take a while to put all of those pieces together," says Carl June, who studies T cells at the University of Pennsylvania in Philadelphia, and is an investigator on another HIV trial involving Sangamo's nuclease. "But it's at least conceivable now." 

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  • #61767

    Gene therapy is a very promising field of study, and yet is incredibly complex and difficult to translate to reality. I think some mainstream problems include; getting the corrected/different copy of a gene into the host cell (attenuated viruses, liposomes, etc.), maintaining the gene once inserted in the host cell and of course the medical ethics and implications of such techniques.

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