Uncovering the early origins of Huntington’s disease using CRISPR engineered embryonic stem cells
Researchers have developed a system to model Huntington’s in human embryonic stem cells…
A team of researchers have developed a system to model Huntington’s in human embryonic stem cells for the first time, by describing early abnormalities in the way Huntington’s neurons look, and how these cells form larger structures that had not previously been associated with the disease.
“Our research supports the idea that the first domino is pushed soon after fertilisation and that has consequences down the line. The final domino falls decades after birth when the symptoms are observable,” says Ali Brivanlou, the Robert and Harriet Heilbrunn Professor at Rockefeller University.
The findings have implications for how to best approach treating the disorder and could ultimately lead to effective therapies.
Huntington’s is one of the few diseases with a straightforward genetic culprit: One hundred percent of people with a mutated form of the Huntingtin (HTT) gene develop the disease. The mutation takes the form of extra DNA and causes the gene to produce a longer-than-normal protein. The DNA itself appears in the form of a repeating sequence, and the more repeats there are, the earlier the disease sets in.
Research on Huntington’s has thus far relied heavily on animal models of the disease and has left many key questions unanswered. For example, scientists have not been able to resolve what function the HTT gene serves normally, or how its mutation creates problems in the brain.
Suspecting that the disease works differently in humans, whose brains are much bigger and more complex than those of lab animals, Prof Brivanlou, along with Research Associates Albert Ruzo and Gist Croft, developed a cell-based human system for their research. They used the gene editing technology CRISPR to engineer a series of human embryonic stem cell lines, which were identical apart from the number of DNA repeats that occurred at the ends of their HTT genes.
“We started seeing things that were completely unexpected,” says Prof Brivanlou. “In cell lines with mutated HTT, we saw giant cells. It looked like a jungle of disorganisation.”
When cells divide, they typically each retain one nuclei. However, some of these enlarged, mutated cells flaunted up to 12 nuclei–suggesting that neurogenesis, or the generation of new neurons, was affected. The disruption was directly proportional to how many repeats were present in the mutation: The more repeats there were, the more multinucleated neurons appeared.
“Our work adds to the evidence that there is an unrecognised developmental aspect to the pathology,” Prof Brivanlou says. “Huntington’s may not be just a neurodegenerative disease, but also a neurodevelopmental disease.”
Treatments for Huntington’s have typically focused on blocking the activity of the mutant HTT protein, the assumption being that the altered form of the protein was more active than normal, and therefore toxic to neurons. However, Prof Brivanlou’s work shows that the brain disruption may actually be due to a lack of HTT protein activity.
To test its function, the researchers created cell lines that completely lacked the HTT protein. These cells turned out to be very similar to those with Huntington’s pathology, corroborating the idea that a lack of the protein–not an excess of it–is driving the disease.
The findings are significant, Prof Brivanlou notes since they indicate that existing treatments that were designed to block HTT activity may actually do more harm than good.
“We should rethink our approach to treating Huntington’s,” he says. “Both the role of the HTT protein and the timing of treatment need to be reconsidered; by the time a patient is displaying symptoms, it may be too late to medicate. We need to go back to the earliest events that trigger the chain reaction that ultimately results in the disease so we can focus new therapies on the cause, not the consequences.”
The researchers hope their new cell lines will be a useful resource for studying the cellular and molecular intricacies of Huntington’s further and suggest they may provide a model for examining other diseases of the brain that are specific to humans.