This is remarkable. The invader agent goes looking for the virus and then makes changes that ends the problem while making the cell immune as well..
We may now manage to actually cure victims.
It also tells us how much we have been advancing.
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Scientists Just Removed HIV from Human Immune Cells Using CRISPR Gene-Editing
http://futurism.com/scientists-just-removed-hiv-human-immune-cells-using-crispr-gene-editing/
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Scientists managed to eliminate HIV-1
DNA from T cell genomes in human lab cultures. It will take time for
advanced use in humans, but it is a remarkable accomplishment.
This is the Power of CRISPR
Using the much-touted CRISPR/Cas9 gene editing method, scientists
have demonstrated how they can edit HIV out of human immune cell DNA,
and in doing so, can prevent the reinfection of unedited cells too.
If you haven’t heard of the CRISPR/Cas9 gene-editing technique
before, get ready to hear a whole lot more about it in 2016, because
it’s set to revolutionise how we investigate and treat the root causes
of genetic disease. It allows scientists to narrow in on a specific
gene, and cut-and-paste parts of the DNA to change its function.
CRISPR/Cas9 is what researchers in the UK have recently gotten approval
to use on human embryos so they can figure out how to improve IVF
success rates and reduce miscarriages, and it’s what Chinese scientists were caught using in 2015 to tweak human embryos on the down-low.
Earlier this year, scientists started using CRISPR/Cas9 to successfully treat a genetic disease – Duchenne muscular dystrophy – in living mammals for the first time, and now it’s showing real potential as a possible treatment for HIV in the future.
The technique works by guiding ‘scissor-like’ proteins to targeted
sections of DNA within a cell, and then prompting them to alter or
‘edit’ them in some way. CRISPR
refers to a specific repeating sequence of DNA extracted from a
prokaryote – a single-celled organism such as bacteria – which pairs up
with an RNA-guided enzyme called Cas9.
So basically, if you want to edit the DNA of a virus within a human
cell, you need a bacterium to go in, encounter the virus, and produce a
strand of RNA that’s identical to the sequence of the virtual DNA.
This ‘guide RNA’ will then latch onto the Cas9 enzyme, and together they’ll search for the matching virus. Once they locate it, the Cas9 gets to cutting and destroying it.
Using this technique, researchers from Temple University managed to
eliminate HIV-1 DNA from T cell genomes in human lab cultures, and when
these cells were later exposed to the virus, they were protected from reinfection.
A new Breakthrough in the fight against HIV
“The findings are important on multiple levels,” says lead researcher Kamel Khalili.
“They demonstrate the effectiveness of our gene editing system in
eliminating HIV from the DNA of CD4 T-cells and, by introducing
mutations into the viral genome, permanently inactivating its
replication.”
“Further,” he adds, “they show that the system can protect cells from
reinfection and that the technology is safe for the cells, with no
toxic effects.”
While gene-editing techniques have been trialled before
when it comes to HIV, this is the first time that scientists have
figured out how to prevent further infections, which is crucial to the
success of a treatment that offers better protection than our current
antiretroviral drugs. Once you stop taking these drugs, the HIV starts
overloading the T-cells again.
“Antiretroviral drugs are very good at controlling HIV infection,” says Khalili. “But patients on antiretroviral therapy who stop taking the drugs suffer a rapid rebound in HIV replication.”
There’s still a lot more work to be done in getting this technique
ready for something more advanced than human cells in a petri dish –
particularly when it comes to perfect accuracy for the ‘cutting’ process
– but it’s an exciting first step.
The results have been published in Scientific Reports.
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