New research suggests that life with rheumatoid arthritis (RA) may become a little more predictable in the future. In a paper in the New England Journal of Medicine (NEJM), researchers from the lab of Robert B. Darnell have identified a new type of cell whose presence in the bloodstream dramatically increases in the week leading up to a flare-up. Methods that detect these cells might one day be developed to predict flares, offering a weather gage for oncoming pain and discomfort.
“If we can reliably identify these new cells in patients, we may be able to tell them ‘You’re about to have a flare,’ so they can prepare themselves,” says Darnell. “This would make flares less disruptive and easier to manage.” In addition, the newly discovered cells may hold a key to understanding the root causes of rheumatoid arthritis—perhaps offering a way to prevent the flares from taking place at all.
Little was known about what causes rheumatoid arthritis symptoms to wax and wane. Rather than looking directly to the affected joints, the Darnell lab thought to examine changes in the blood leading up to a flare. The group studies RNA and its connection to diseases like cancer and neurological disease. For this experiment, they chose to use longitudinal RNA sequencing, a method of analyzing gene expression over long periods of time to observe any changes during disease states. This technique could pinpoint any molecular variations as arthritis symptoms came and went.
To do this research the right way, the lab needed a lot of data. Rheumatoid arthritis patients normally come to the hospital for monthly bloodwork, but the scientists wanted to see how the blood changed on a weekly basis. Rather than having patients come in every week, they developed a finger-prick kit for collecting samples from home. Over a period of four years, patients mailed their blood samples to the lab and reported their symptoms, noting when flares occurred. Later on, the researchers analyzed blood collected the weeks before symptoms worsened.
The first observation was not entirely unsurprising: About two weeks before a flare, lab members saw increased activity from B cells, which create antibodies—a common trait of autoimmune disorders. But things got more interesting in the samples collected a week later, in the days just prior to a flare. There, the scientists noticed a signature for a cell that did not match any known cell type. The cells were normally present in low levels in the blood, then spiked in the week before a flare, and all but disappeared during the flare itself. They named their new discovery PRIME cells. And PRIME cells did not look anything like what is normally found in the bloodstream.
The function of PRIME cells remains to be established—but the scientists already have some clues. Based on RNA expression profiles, they found these cells to be strikingly similar to synovial fibroblasts, which are found in the tissue linings of joints. Darnell believes that PRIME cells may be precursors to these fibroblasts, which are known to play a role in causing rheumatoid arthritis symptoms. For example, in mouse experiments where scientists removed these fibroblasts from an inflamed joint, and transplanted them to a healthy one, the latter joint became arthritic too.
Lab members are now working to learn as much as possible about PRIME cells, and how to quickly detect them. If doctors can easily test for the presence of PRIME cells in the blood one day, they may be able to provide patients with forecasts of oncoming flares to make symptoms less disruptive. Moreover, if it turns out that PRIME cells are indeed causing the flares, their discovery may open the door to developing therapies that nip inflammation in the bud.