Mice have been made resistant to HIV by sabotaging a gene in the blood cells that the virus normally infects.
Researchers who developed the treatment at Sangamo BioSciences, a biotechnology company in Duarte, California, US, hope to test it in patients by the end of 2008. If successful, the treatment could offer a more effective way for controlling HIV in patients with the disease, the researchers say.
Once the gene has been altered, the cells can no longer make CCR5, a surface protein to which the virus attaches itself before sneaking inside. With no "door handle" to hold onto, the virus can no longer infect the cell.
To sabotage the gene that makes CCR5, they used a harmless virus to sneak a molecule called a zinc-finger nuclease into the cells.
Permanent change
The "zinc-finger" part of the molecule targets and binds exclusively to genetic material found only in the CCR5 gene. The "nuclease" section is an enzyme that snips open and alters the gene so that it can no longer make the CCR5 protein.
After this process, the cell is then effectively immune to infection by HIV. "Once the job is done, the cell DNA is altered permanently," says Elena Perez at the Children's Hospital of Philadelphia in Pennsylvania, who collaborated on the study.
Half the mice received human T-cells treated with the zinc-finger nucleases, and the other half received untreated T-cells. Later the mice were infected with HIV.
Inherited trait
After six weeks, all the treated mice had become resistant to the virus. "We saw a tenfold suppression of the virus in the treated mice compared with controls," says Philip Gregory of Sangamo, "and we saw a five-fold increase in the number of circulating T-cells, [which are] usually attacked by HIV."
In human trials, Sangamo plans to extract T-cells from HIV-infected patients, treat them in the lab to alter the gene that makes CCR5, then return them to the bloodstream.
The hope is that because these cells are resistant to HIV, as they multiply they will become the dominant type within the body. They could then provide longer-term protection than drugs that deny HIV access to cells by physically blocking CCR5 molecules.
"What's really exciting is that the change in the genome is permanent, and inherited by all 'daughter' T-cells created when the altered T-cells multiply," says Gregory.
Drug fallback
"The zinc-finger approach has significant potential compared to other strategies," says Ed Berger, a researcher credited with helping establish the CCR5-HIV link at the National Institutes of Health in Bethesda, Maryland, US.
"With genetic knockout of CCR5 by the zinc finger, the cells lacking CCR5 have a selective advantage," he says.
Berger adds that, unlike other approaches where patients have to carry on taking CCR5 blockers, or which depend on molecules that must continuously stop CCR5 working, the zinc finger only has to do one operation, and the job is complete.
John Moore, co-discoverer of the link between CCR5 and HIV in 1996, says the science is excellent, but doubts whether the gene can be sabotaged in enough T-cells to make a difference to patients.
He says that in any case, Maraviroc - a CCR5 blocking drug launched last year by Pfizer in the US and Europe - works well, and that others are in advanced clinical trials.
Journal reference: Nature Biotechnology (DOI: 10.1038/nbt1410)
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Have your say
Dangerous Territory. . .
Mon Jun 30 16:42:18 BST 2008 by Megan
Can somebody say "I am Legend?"
What Does Ccr5 Normally Do?
Mon Jun 30 16:45:07 BST 2008 by Daniel Dugour
Don't we need this CCR5? I would like to know what the side effects are of blocking CCR5 production in T-Cells. I suppose this protein is there for a reason, I assume it would have been gone or been replaced by another protein if it has no function.
The drugs that block the CCR5 work differently, in that the protein is still present in the cell wall and thus is still available for its functions there. But what happens if it is not there anymore?
What Does Ccr5 Normally Do?
Mon Jun 30 17:27:42 BST 2008 by Ron
Many people are walking around fine with a non-functional CCR5. It is called the delta32 homozygous deletion and makes these indivuals naturally resistant to HIV. This was actually how the HIV CCR5 co-receptor was discovered. If successful, this treatmen will not be a cure, but might allow for a more sustainable immune response in AIDS patients and therefore a longer healthier existence. Small molecule CCR5 antagonists work as well too, further suggesting this as a valid approach.
What Does Ccr5 Normally Do?
Mon Jun 30 18:51:10 BST 2008 by Evan
I am sure there is some purpose for the CCR5 receptor.
However, current drugs that significantly block the action of CCR5 actually improve the life expectancy of HIV-infected people, so it can't be that important.
Much more clear-cut is the function of the T-Cells, which help fight many types of infections. Once the T-Cells are destroyed by HIV, the victim falls prey to many normally-harmless diseases.
Sacrificing a non-essential receptor to preserve an essential cell-type sounds like a sensible tradeoff for someone who is facing a death sentence.
What Does Ccr5 Normally Do?
Mon Jun 30 20:10:01 BST 2008 by Karsten Jensen
It's likely, or at least possible, that the CCR5 protein has had some importance in earlier ancestors to the human race, but now is superfluous. In that case, it won't make any difference at all to knock it out - except inhibiting HIV (and Yersinia pestis).
What Does Ccr5 Normally Do?
Tue Jul 01 15:19:04 BST 2008 by Wibblus Wobblus
CCR5 is important in chemotaxis and motility under certain circumtances in certain cell types. CCR5 small molecule inhibitors can't distinguish bewteen T cells and other cell types, and can have off-traget effects and pharmacokinetic issues. Maybe stopping CCR5 expression in just T cells is a good idea? But will there be enough delivery? Will it cause cancer?
Inheritance
Mon Jun 30 16:52:16 BST 2008 by Diskjunky
If the change is permanent, what effect does this have on any offspring produced by the patients after treatment?
Inheritance
Mon Jun 30 17:01:00 BST 2008 by Adam Mitchell
The CCR5 gene is only knocked out of the T cell, only replications of this cell will contain this genetic change.
Since the change is not made to sperm or egg cell progenitors, and T-Cells do not change into them. This modification will not be transmitted to the offspring.
Inheritance
Tue Jul 01 01:10:35 BST 2008 by Dave
Big assumption. Direct you to "Lamarck's Signature" by Steele et al., available on Amazon etc etc.
Not my field, but I understand there's some evidence for immune system copying during breastfeeding as well. Do correct me if I've overstepped there.
More importantly, if the offspring still inherit the HIV, you might have to treat everybody (pharmaceutical's dream!)
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