Friday, May 18, 2012

Delivery system for gene therapy may help treat arthritis




Researchers report that a DNA-covered submicroscopic bead used to deliver genes or drugs directly into cells to treat disease appears to have therapeutic value just by showing up.

Within a few hours of injecting empty-handed DNA nanoparticles, Georgia Health Sciences University researchers were surprised to see increased expression of an enzyme that calms the immune response.
Researchers report in the study featured on the cover of The Journal of Immunology that the enhanced expression of indoleamine 2,3 dioxygenase, or IDO, significantly reduced the hallmark limb joint swelling and inflammation of this debilitating autoimmune disease in an animal model of rheumatoid arthritis.


“It’s like pouring water on a fire,” said Dr. Andrew L. Mellor, Director of the GHSU’s Medical College of Georgia Immunotherapy Center and the study’s corresponding author. “The fire is burning down the house, which in this case is the tissue normally required for your joints to work smoothly,” Mellor said of the immune system’s inexplicable attack on bone-cushioning cartilage. “When IDO levels are high, there is more water to control the fire.”
Several delivery systems are used for gene therapy, which is used to treat conditions including cancer, HIV infection and Parkinson’s disease. The new findings suggest the DNA nanoparticle technique is also valuable for autoimmune diseases such as arthritis, type 1 diabetes and lupus. “We want to induce IDO because it protects healthy tissue from destruction by the immune system,” Mellor said.
The researchers were exploring IDO’s autoimmune treatment potential by inserting the human IDO gene into DNA nanoparticles. They hoped to enhance IDO expression in their arthritis model when Dr. Lei Huang, Assistant Research Scientist and the paper’s first author, serendipitously found that the DNA nanoparticle produced the desired result. Exactly how and why is still being pursued. Early evidence suggests that immune cells called phagocytes, white blood cells that gobble up undesirables like bacteria and dying cells, start making more IDO in response to the DNA nanoparticle’s arrival. “Phagocytes eat it and respond quickly to it, and the effect we measure is IDO,” Mellor said.
Dr. Tracy L. McGaha, a GHSU immunologist and co-author of the current study, recently discovered that similar cells also prevented the development of systemic lupus erythematosus in mice.
Follow-up studies include documenting all cells that respond by producing more IDO. GHSU researchers work with biopolymer experts at the Massachusetts Institute of Technology, the University of California, Berkeley and the Georgia Institute of Technology to identify the optimal polymer.
The polymer used in the study is not biodegradable, so the researchers need one that will eventually safely degrade in the body. Ideally, it would also target specific cells, such as those near inflamed joints, to minimise any potential ill effects.
“It’s like a bead, and you wrap the DNA around it,” Mellor said of the polymer. While the DNA does not have to carry anything to get the desired response, in this case, DNA itself is essential to make cells express IDO. To ensure that IDO expression was responsible for the improvements, they also performed experiments in mice given an IDO inhibitor in their drinking water and in mice genetically altered to not express IDO. “Without access to the IDO pathway, the therapy no longer works,” Mellor said.
Drs. Andrew Mellor and David Munn reported in 1998 in the journal Science that the fetus expresses IDO to help avoid rejection by the mother’s immune system. Subsequent studies have shown that tumours also use IDO for protection, and clinical trials are studying the tumour-fighting potential of an IDO inhibitor. On the flip side, there is evidence that increasing IDO expression can protect transplanted organs and counter autoimmune disease.
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Mellor is the Bradley-Turner and Georgia Research Alliance Eminent Scholar in Molecular Immunogenetics at MCG. The research was funded by the Carlos and Marguerite Mason Trust and the National Institutes of Health, and a patent is pending on the findings.

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