The scientists identified this bouncer, a protein called P21, which prevents immune cells from launching into their destructive rampage through the cartilage and bone. When the researchers developed and injected an imitation of the protein into an animal model of rheumatoid arthritis, the disease process was halted.
"The bouncer molecule stopped the immune cells from going crazy," said Professor Harris Perlman of Northwestern's Feinberg School. "Imagine destructive customers in a bar, and the bouncer says, 'You are going to behave!' That's P21. This discovery opens up a new avenue for future therapies, which are greatly needed for rheumatoid arthritis."
Previous research by the Feinberg team showed people with rheumatoid arthritis were low in P21, but the protein's role was unknown. The new study reveals the protein's vital role in keeping the immune cells in check.
Currently, there is no effective, nontoxic way to stop the hyperactive immune cells, Perlman said.
To develop the new approach, Perlman and his team tested five different parts, called peptides, of P21. He slipped each peptide into a "ghostlike" molecule that he injected into mice with a rheumatoid arthritis-like disease. The molecule secretly infiltrated the immune cells. After the seven-day trial, one of the tested peptides had calmed the overactive immune cells without toxic effects. Next, Perlman plans a 30-day study with the same peptide to monitor efficacy and toxicity over a longer period of time.
Existing treatments for rheumatoid arthritis include low-level chemotherapy and steroids. These are not always effective, however, and they are frequently accompanied by side effects. A newer class of therapy, which is sometimes used in combination with chemotherapy and steroids, is biologic response modifiers.
These are antibodies or other proteins that reduce the inflammation produced by the hyperactive immune cells. These biologics don't work for everyone, though, and can be associated with side effects including the risk of infection.
MEDICA.de; Source: Northwestern University Feinberg School of Medicine