System combining gene therapy with tissue engineering could avoid the need for frequent injections of recombinant drugs
BOSTON, Nov. 15, 2011 /PRNewswire-USNewswire/ -- Patients who rely on recombinant, protein-based drugs must often endure frequent injections, often several times a week, or intravenous therapy. Researchers at Children's Hospital Boston demonstrate the possibility that blood vessels, made from genetically engineered cells, could secrete the drug on demand directly into the bloodstream. In the November 17 issue of the journal Blood, they provide proof-of-concept, reversing anemia in mice with engineered vessels secreting erythropoietin (EPO).
The technology could potentially be used to deliver other proteins such as Factor VIII and Factor IX for patients with hemophilia, alpha interferon for hepatitis C and interferon beta for multiple sclerosis, says the study's principal investigator, Juan Melero-Martin, PhD, of the Department of Cardiac Surgery at Children's.
Such drugs are currently made in bioreactors by engineered cells, and are very expensive to make in large amounts. "The paradigm shift here is, 'why don't we instruct your own cells to be the factory?'" says Melero-Martin, also an assistant professor at Harvard Medical School.
The researchers created the drug-secreting vessels by isolating endothelial colony-forming cells from human blood and inserting a gene instructing the cells to produce EPO. They then added mesenchymal stem cells, suspended the cells in a gel, and injected this mixture into the mice, just under the skin. The cells spontaneously formed networks of blood vessels, lined with the engineered endothelial cells. Within a week, the vessels hooked up with the animals' own vessels, releasing EPO into the bloodstream.
Tests showed that the drug circulated throughout the body and reversed anemia in the mice, both induced by radiation (as often occurs in cancer patients) and by loss of kidney tissue (modeling chronic kidney failure). Mice with the vessel implants had significantly higher hematocrits (a measure of red blood cell concentration) and recovered from anemia more quickly than controls.
The system also had a built-in on/off control: the inserted EPO-encoding gene was linked to a repressor protein that prevented it from being turned on unless the mice were given the oral drug doxycycline (added to their drinking water). Doxycycline disabled the repressor protein, allowing EPO to be made. When doxycycline was added to the water on a weekly on/off schedule, the animals' hematocrit fluctuated accordingly. When hematocrit reached a normal level, the system could be switched off by simply giving them plain water.
Melero-Martin and colleagues are looking at ways to deliver doxycycline through the skin to avoid exposing the whole body to an antibiotic. There are also other ways to design the genetic on/off control, using synthetic systems or even regulatory elements used naturally by the body – sensing blood oxygen levels and stimulating EPO production when oxygen levels dip.
A traditional barrier to gene therapy has been getting the genetically altered cells to engraft and stay in place. Blood-vessel implants are an ideal platform technology for gene therapy applications whose goal is systemic drug delivery, says Melero-Martin.
"Blood vessels are one of the few tissues where we have good control over engraftment," he says. "Endothelial cells are easily isolated from blood, are good at assembling themselves into blood vessels, and are ideal for releasing compounds into the bloodstream, since they line the blood vessels."
The lab is interested in trying this system with other therapeutic proteins, and is also exploring ways to get cells to release therapeutics at a moment's notice by getting accumulating stores in advance that could be released upon the proper signal, as beta cells in the pancreas do with insulin, for example.
In addition, Melero-Martin wants to explore regenerative medicine applications, creating blood vessels with genetic instructions to produce factors that attract stem cells or induce cells to differentiate.
The study was funded by the National Institute of Biomedical Imaging and Bioengineering (NIBIB) of the National Institutes of Health and the Children's Hospital Boston Department of Cardiac Surgery. Ruei-Zeng Lin, PhD, a research fellow in the Department of Cardiac Surgery at Children's, was first author on the paper.
Children's Hospital Boston is home to the world's largest research enterprise based at a pediatric medical center, where its discoveries have benefited both children and adults since 1869. More than 1,100 scientists, including nine members of the National Academy of Sciences, 11 members of the Institute of Medicine and nine members of the Howard Hughes Medical Institute comprise Children's research community. Founded as a 20-bed hospital for children, Children's Hospital Boston today is a 395 bed comprehensive center for pediatric and adolescent health care grounded in the values of excellence in patient care and sensitivity to the complex needs and diversity of children and families. Children's also is the primary pediatric teaching affiliate of Harvard Medical School. For more information about research and clinical innovation at Children's, visit: http://vectorblog.org.
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SOURCE Children's Hospital Boston