Patient-specific stem cells and personalised gene therapy

12 Jul 2014

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Columbia University Medical Center (CUMC) researchers have created a way to develop personalised gene therapies for patients with retinitis pigmentosa (RP), a leading cause of vision loss. The approach, the first of its kind, takes advantage of induced pluripotent stem (iPS) cell technology to transform skin cells into retinal cells, which are then used as a patient-specific model for disease study and preclinical testing.

 
Images of normal (above) and diseased retinas. Patients with MFRP mutations, a cause of retinitis pigmentosa, lose the function of most retinal cells, particularly at the periphery of the retina, leaving them with drastically reduced vision. Personalised gene therapy, using iPS cells, may offer a way to correct this genetic disorder.(Image credit: Lab of Stephen H. Tsang, MD, PhD/Columbia University Medical Center.)  

Using this approach, researchers led by Stephen H. Tsang, MD, PhD, showed that a form of RP caused by mutations to the gene MFRP (membrane frizzled-related protein) disrupts the protein that gives retinal cells their structural integrity. They also showed that the effects of these mutations can be reversed with gene therapy. The approach could potentially be used to create personalized therapies for other forms of RP, as well as other genetic diseases. The paper was published recently in the online edition of Molecular Therapy, the official journal of the American Society for Gene & Cell Therapy.

''The use of patient-specific cell lines for testing the efficacy of gene therapy to precisely correct a patient's genetic deficiency provides yet another tool for advancing the field of personalised medicine,'' said Dr. Tsang, the Laszlo Z. Bito Associate Professor of Ophthalmology and associate professor of pathology and cell biology.

While RP can begin during infancy, the first symptoms typically emerge in early adulthood, starting with night blindness. As the disease progresses, affected individuals lose peripheral vision. In later stages, RP destroys photoreceptors in the macula, which is responsible for fine central vision. RP is estimated to affect at least 75,000 people in the United States and 1.5 million worldwide.

More than 60 different genes have been linked to RP, making it difficult to develop models to study the disease. Animal models, though useful, have significant limitations because of interspecies differences. Researchers also use human retinal cells from eye banks to study RP. As these cells reflect the end stage of the disease process, however, they reveal little about how the disease develops.

There are no human tissue culture models of RP, as it would be dangerous to harvest retinal cells from patients. Finally, human embryonic stem cells could be useful in RP research, but they are fraught with ethical, legal, and technical issues.

The use of iPS technology offers a way around these limitations and concerns. Researchers can induce the patient's own skin cells to revert to a more basic, embryonic stem cell-like state. Such cells are ''pluripotent,'' meaning that they can be transformed into specialised cells of various types.

In the current study, the CUMC team used iPS technology to transform skin cells taken from two RP patients - each with a different MFRP mutation - into retinal cells, creating patient-specific models for studying the disease and testing potential therapies.

By analysing these cells, the researchers found that the primary effect of MFRP mutations is to disrupt the regulation of actin, the protein that makes up the cytoskeleton, the scaffolding that gives the cell its structural integrity. ''Normally, the cytoskeleton looks like a series of connected hexagons,'' said Dr Tsang. ''If a cell loses this structure, it loses its ability to function.''

The researchers also found that MFRP works in tandem with another gene, CTRP5, and that a balance between the two genes is required for normal actin regulation.

In the next phase of the study, the CUMC team used adeno-associated viruses (AAVs) to introduce normal copies of MFRP into the iPS-derived retinal cells, successfully restoring the cells' function. The researchers also used gene therapy to ''rescue'' mice with RP due to MFRP mutations. According to Dr. Tsang, the mice showed long-term improvement in visual function and restoration of photoreceptor numbers.

''This study provides both in vitro and in vivo evidence that vision loss caused by MFRP mutations could potentially be treated through AAV gene therapy,'' said coauthor Dieter Egli, PhD, an assistant professor of developmental cell biology (in pediatrics) at CUMC, who is also affiliated with the New York Stem Cell Foundation.

Dr Tsang thinks this approach could also be used to study other forms of RP. ''Through genome-sequencing studies, hundreds of novel genetic spelling mistakes have been associated with RP,'' he said. ''But until now, we've had very few ways to find out whether these actually cause the disease. In principle, iPS cells can help us determine whether these genes do, in fact, cause RP, understand their function, and, ultimately, develop personalized treatments.''

 
In normal, or wild-type, retinal cells (left), the protein actin forms the cell's cytoskeleton, creating aninternal support structure that looks like a series of connected hexagons. In cells with MFRP mutations Z (centre), this structure fails to form, compromising cellular function. When diseased retinal cells are treated with gene therapy to insert normal copies of MFRP (right), the cell's cytoskeleton and function are restored. (Image credit: Lab of Stephen H. Tsang, MD, PhD/Columbia University Medical Center.)  

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