New research from Queen Mary University of London, published in Nature Medicine, has shown that molecular profiling of the diseased joint tissue can significantly impact whether specific drug treatments will work to treat rheumatoid arthritis (RA) patients. The researchers also identified specific genes associated with resistance to most available drugs therapies, commonly referred to as refractory disease, which could provide the key to developing new, successful drugs to help these people.

While there has been much progress made over the past decades in treating arthritis, a significant number of patients (approximately 40%) do not respond to specific drug therapies, and 5-20% of people with the disease are resistant to all current forms of medication.

The researchers carried out a biopsy-based clinical trial, involving 164 arthritis patients, in which their responses to either rituximab or tocilizumab – two drugs commonly used to treat RA – were tested. The results of the original trial published in The Lancet in 2021 demonstrated that in those patients with a low synovial B-cell molecular signature only 12% responded to a medication that targets B cells (rituximab), whereas 50% responded to an alternative medication (tocilizumab). When patients had high levels of this genetic signature, the two drugs were similarly effective.

As part of the first-of-its-kind study, funded by the Efficacy and Mechanism Evaluation (EME) Programme, an MRC and NIHR partnership, the Queen Mary team also looked at the cases where patients did not respond to treatment via any of the drugs and found that there were 1,277 genes that were unique to them specifically.

Building on this, the researchers applied a data analyses technique called machine learning models to develop computer algorithms which could predict drug response in individual patients. The machine learning algorithms, which included gene profiling from biopsies, performed considerably better at predicting which treatment would work best compared to a model which used only tissue pathology or clinical factors.

The study strongly supports the case for performing gene profiling of biopsies from arthritic joints before prescribing expensive so-called biologic targeted therapies. This could save the NHS and society considerable time and money and help avoid potential unwanted side-effects, joint damage, and worse outcomes which are common amongst patients. As well as influencing treatment prescription, such testing could also shed light on which people may not respond to any of the current drugs on the market, emphasising the need for developing alternative medications.

Professor Costantino Pitzalis, Versus Arthritis Professor of Rheumatology at Queen Mary University of London, said: “Incorporating molecular information prior to prescribing arthritis treatments to patients could forever change the way we treat the condition. Patients would benefit from a personalised approach that has a far greater chance of success, rather than the trial-and-error drug prescription that is currently the norm.

“These results are incredibly exciting in demonstrating the potential at our fingertips, however, the field is still in its infancy and additional confirmatory studies will be required to fully realise the promise of precision medicine in RA.

“The results are also important in finding solutions for those people who unfortunately don’t have a treatment that helps them presently. Knowing which specific molecular profiles impact this, and which pathways continue to drive disease activity in these patients, can help in developing new drugs to bring better results and much-needed relief from pain and suffering.”

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The inflammation signal (IL-6 amplifier) in the affected joint (L) causes the secretion of ATP that transmits a signal through the spinal cord (DRG, L5), which in turn triggers an increase in ATP concentrations in the unaffected joint (R) that results in inflammation in that joint (Rie Hasebe, et al. Journal of Experimental Medicine. May 17, 2022).

Adenosine triphosphate (ATP) secreted from sensory neuron-interneuron crosstalk is key to the spreading of inflammation across joints, acting as a neurotransmitter and inflammation enhancer.

Rheumatoid arthritis is a chronic inflammatory autoimmune disorder that primarily affects joints. One of the key features of this disease is remote inflammation, where inflammation spreads from one joint to another. Research has shown that neural circuits or cells migrated from the joints are involved in inflammation spread, but the detailed mechanism by which this occurs has not been elucidated.

A team of researchers from Japan and the USA, led by Professor Masaaki Murakami at Hokkaido University,  have revealed that remote inflammation spreads by neuron crosstalk, and that adenosine triphosphate (ATP) plays a key role in this process. Their findings, published in the Journal of Experimental Medicine, may lead to new therapies and treatments for inflammatory diseases.

Inflammation is a part of the natural immune response that occurs in response to infection or irritation. It is a process by which the immune system, involving immune cells, blood vessels, and molecular mediators, attempts to clear out the pathogens and damaged cells and thereafter repair the damage. However, excessive inflammation is a disorder in itself, and is seen in diseases such as hay fever, atherosclerosis, psoriasis, and rheumatoid arthritis, among others.

In this study, the authors used previous observations of the gateway reflex—an immune response mechanism whereby specific neural signals change the state of specific blood vessels to allow immune cells to enter tissue, leading to local inflammation—to hypothesize that neural crosstalk could be responsible for remote inflammation.

They tested this hypothesis through experiments in rheumatoid arthritis models in mice. The mice were divided into control and test groups. In the test groups, the sensory neural circuits between the left and right ankle joints were interrupted. Arthritis of the left ankle was then induced in both sets of mice and the spread of arthritis to the right ankle was observed.

Their results showed that the inflammation signal in one joint is transmitted to the other via a sensory neuron connection through the spinal cord, leading to inflammation in both joints. Specifically, inflammation in one joint led to an increase of ATP in both joints, which triggered an increase of a signal molecule that resulted in inflammation. Blocking this pathway prevented the spread of inflammation.

As this study was performed in mice models, it is necessary to determine if the findings apply to rheumatoid arthritis and other chronic inflammatory diseases in humans. If so, it could provide a therapeutic target for various diseases with spreading inflammation.

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