The ALS Association and the Packard Center Partner to Develop Animal Model Systems for Most Common Cause of Familial ALS
The ALS Association and the Robert Packard Center for ALS Research at Johns Hopkins have entered into a partnership to expedite the development of animal model systems to expand the knowledge about the C9ORF72 gene, which has been identified as the most common cause of inherited amyotrophic lateral sclerosis (ALS or Lou Gehrig’s Disease) and Frontotemporal dementia (FTD).
In October, 2011, a large expansion of a hexanucleotide GGGGCC repeat was discovered in the C9ORF72 gene, but how the expansion causes malfunction of the nerve cells in ALS and FTD remains unknown. It is thought that the messenger RNA (mRNA) derived from this large repeat aberrantly accumulates. This scenario is reminiscent of what is known in other diseases caused by expanded repeats, especially myotonic dystrophy.
Building on that example and in partnership with Isis Pharmaceuticals, the Cleveland Laboratory in San Diego, Calif., has designed a gene silencing approach to develop a drug called an antisense oligonucleotide (ASO) that will selectively destroy the ALS-causing mRNA with the expanded repeat. Essential for drug development is a mouse model expressing the expanded human C9ORF72 mRNA. The investigators will build these models and use them to validate efficacy of the ASO drug. This research was funded by ALS Association California Chapters through a state program that allows taxpayers to direct donations toward the “ALS/Lou Gehrig’s Disease Fund” when completing state tax forms.
A parallel effort to inactivate the toxic C9orf 72 gene and identify drug activity biomarkers in ALS patients is also underway at the Packard Center with Bryan Traynor, of the Laboratory of Neurogenetics, National Institute on Aging and Johns Hopkins Univ. and Jeff Rothstein, the Packard Center director.
In addition, the mouse model may develop an ALS-like disease, which can be used to determine exactly what goes wrong in the presence of the aberrant mRNA. Complementary mouse models will be generated by a group of researchers from Johns Hopkins, which will focus on developing tools to understand the mechanisms resulting from the abnormally expanded repeats on C9ORF72 and point to new directions for the treatment of this devastating disease.
Initially, lead researcher Philip Wong and his colleagues plan to develop mouse model systems to find out if losing C9ORF72 gene activity is responsible for death of motor neurons. Secondly, they hope to learn whether toxicity arises through the presence of a toxic RNA derived from the diseased C9ORF72 gene that determines malfunction of motor nerve cells.
Outcomes from these studies will clarify how hexanucleotide repeat expansion in the C9ORF72 gene causes motor nerve cell loss in a large proportion of cases of ALS. In addition, these efforts will have important implications for therapy design and provide useful mouse model systems for testing therapies that could eventually benefit people with ALS.
The mouse models developed through this initiative will be made rapidly available to researchers through the ALS Mouse Repository at Jackson Laboratories funded by a partnership with The ALS Association, Tow Foundation and ALS Therapy Alliance. For more information visit www.alsa.org/news/archive/tow-foundation-challenge.html.
The discovery of the C9ORF72 genetic repeat, made by Bryan Traynor was funded by The ALS Association and the Packard Center. Another study reported at the same time with similar findings was led by Rosa Rademakers, Mayo Clinic; this study was also funded by The ALS Association. For additional information about the C9ORF72 studies visit web.alsa.org/site/PageNavigator/research_update_9_21_11.html and www.alscenter.org/news/rss_from_the_packard_center/11_09_21.html.
Source: The ALS Association