Johns Hopkins researchers report concrete steps in the use of human stem
cells to test how diseased cells respond to drugs. Their success
highlights a pathway toward faster, cheaper drug development for some
genetic illnesses, as well as the ability to pre-test a therapy's safety
and effectiveness on cultured clones of a patient's own cells.
he project, described in an article published November 25 on the website of the journal Nature Biotechnology,
began several years ago, when Gabsang Lee, D.V.M., Ph.D., an assistant
professor at the Johns Hopkins University School of Medicine's Institute
for Cell Engineering, was a postdoctoral fellow at Sloan-Kettering
Institute in New York. To see if induced pluripotent stem cells (iPSCs)
could be used to make specialized disease cells for quick and easy drug
testing, Lee and his colleagues extracted cells from the skin of a
person with a rare genetic disease called Riley-Day syndrome, chosen
because it affects only one type of nerve cell that is difficult if not
impossible to extract directly from a traditional biopsy. These traits
made Riley-Day an ideal candidate for alternative ways of generating
cells for study.
In a so-called "proof of concept" experiment, the researchers
biochemically reprogrammed the skin cells from the patient to form
iPSCs, which can grow into any cell type in the body. The team then
induced the iPSCs to grow into nerve cells. "Because we could study the
nerve cells directly, we could for the first time see exactly what was
going wrong in this disease," says Lee. Some symptoms of Riley-Day
syndrome are insensitivity to pain, episodes of vomiting, poor
coordination and seizures; only about half of affected patients reach
age 30.
In the recent research at Johns Hopkins and Memorial Sloan-Kettering,
Lee and his co-workers used these same lab-grown Riley-Day nerve cells
to screen about 7,000 drugs for their effects on the diseased cells.
With the aid of a robot programmed to analyze the effects, the
researchers quickly identified eight compounds for further testing, of
which one -- SKF-86466 -- ultimately showed promise for stopping or
reversing the disease process at the cellular level.
Lee says a clinical trial with SKF-86466 might not be feasible
because of the small number of Riley-Day patients worldwide, but
suggests that a closely related version of the compound, one that has
already been approved by the U.S. Food and Drug Administration for
another use, could be employed for the patients after a few tests.
The implications of the experiment reach beyond Riley-Day syndrome,
however. "There are many rare, 'orphan' genetic diseases that will never
be addressed through the costly current model of drug development," Lee
explains. "We've shown that there may be another way forward to treat
these illnesses."
Another application of the new stem cell process could be treatments
tailored not only to an illness, but also to an individual patient, Lee
says. That is, iPSCs could be made for a patient, then used to create a
laboratory culture of, for example, pancreatic cells, in the case of a
patient with type 1 diabetes. The efficacy and safety of various drugs
could then be tested on the cultured cells, and doctors could use the
results to help determine the best treatment. "This approach could move
much of the trial-and-error process of beginning a new treatment from
the patient to the petri dish, and help people to get better faster,"
says Lee.
Other authors of the paper are Christina N. Ramirez, Ph.D., Nadja
Zeltner, Ph.D., Becky Liu, Constantin Radu, M.S., Bhavneet Bhinder,
Hakim Djaballah, Ph.D., and Lorenz Studer, Ph.D., of the Sloan-Kettering
Institute; and Hyesoo Kim, Ph.D., Young Jun Kim, M.D., Ph.D., InYoung
Choi, Ph.D., and Bipasha Mukherjee-Clavin of the Johns Hopkins
University School of Medicine.
The work was supported by funds from New York State Stem Cell Science
(NYSTEM), the New York Stem Cell Foundation (NYSCF), the state of
Maryland (TEDCO, MSCRF), the Commonwealth Foundation for Cancer
Research, the Experimental Therapeutics Center at Memorial
Sloan-Kettering Cancer Center, the William Randolph Hearst Fund in
Experimental Therapeutics, the L.S. Wells Foundation, and the National
Cancer Institute (grant number 5 P30 CA008748-44).
Journal Reference:
- Gabsang Lee, Christina N Ramirez, Hyesoo Kim, Nadja Zeltner, Becky Liu, Constantin Radu, Bhavneet Bhinder, Yong Jun Kim, In Young Choi, Bipasha Mukherjee-Clavin, Hakim Djaballah, Lorenz Studer. Large-scale screening using familial dysautonomia induced pluripotent stem cells identifies compounds that rescue IKBKAP expression. Nature Biotechnology, 2012; DOI: 10.1038/nbt.2435
Courtesy: ScienceDaily
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