Role of pharmacological activity of autoantibodies in ME/CFS
Lead Research Organisation:
University of Nottingham
Department Name: School of Life Sciences
Abstract
Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS) is a condition characterised by extreme fatigue, memory impairment, pain and other symptoms that vary from patient to patient. It affects about 0.9% of the population and is often triggered by an acute viral or bacterial infection, such as Epstein-Barr virus. The underlying physiological and molecular basis of ME/CFS is unknown, and no effective treatments exist.
One proposed mechanism is that the blood flow is altered by autoantibodies against receptors involved in blood flow regulation. Antibodies are generated by the immune system to recognise intruders and under normal conditions, our immune system is trained not to attack our own tissues. However, during a severe infection, the immune system adopts an "all hands on deck" approach, which results in some of the newly-produced antibodies escaping quality control and targeting our own tissues, autoantibodies. Receptors regulation blood flow are located in walls of blood vessels and cause a blood vessel to dilate or contract as the demand for oxygen and nutrients to tissues such as the brain or muscles changes. Research has found increased levels of these autoantibodies in ME/CFS patients and initial trials removing these autoantibodies from the blood using a technique called immunoadsorption have shown improvement in symptoms.
In this project, we will test the hypothesis that autoantibodies can activate or inhibit the receptors responsible for the blood flow regulation, in a similar way medical drugs are used to regulate blood pressure.
We aim to profile serum samples from 325 ME/CFS patients and 130 healthy individuals to determine the presence of autoantibodies against all thirty receptors involved in blood pressure regulation. Importantly, we will study the ability of autoantibodies detected in each sample to activate or inhibit these receptors in order to test the hypothesis that the activity of these autoantibodies is a decisive factor in the disease.
If our hypothesis is correct, we will be able to develop an accurate blood test that may be able to detect ME/CFS earlier or to independently confirm the diagnosis. Ultimately, we hope that these results may also indicate a possible route for therapeutic intervention to counteract the effects of autoantibodies and alleviate the ME/CFS symptoms using a combination of already existing drugs, specific for each individual case.
One proposed mechanism is that the blood flow is altered by autoantibodies against receptors involved in blood flow regulation. Antibodies are generated by the immune system to recognise intruders and under normal conditions, our immune system is trained not to attack our own tissues. However, during a severe infection, the immune system adopts an "all hands on deck" approach, which results in some of the newly-produced antibodies escaping quality control and targeting our own tissues, autoantibodies. Receptors regulation blood flow are located in walls of blood vessels and cause a blood vessel to dilate or contract as the demand for oxygen and nutrients to tissues such as the brain or muscles changes. Research has found increased levels of these autoantibodies in ME/CFS patients and initial trials removing these autoantibodies from the blood using a technique called immunoadsorption have shown improvement in symptoms.
In this project, we will test the hypothesis that autoantibodies can activate or inhibit the receptors responsible for the blood flow regulation, in a similar way medical drugs are used to regulate blood pressure.
We aim to profile serum samples from 325 ME/CFS patients and 130 healthy individuals to determine the presence of autoantibodies against all thirty receptors involved in blood pressure regulation. Importantly, we will study the ability of autoantibodies detected in each sample to activate or inhibit these receptors in order to test the hypothesis that the activity of these autoantibodies is a decisive factor in the disease.
If our hypothesis is correct, we will be able to develop an accurate blood test that may be able to detect ME/CFS earlier or to independently confirm the diagnosis. Ultimately, we hope that these results may also indicate a possible route for therapeutic intervention to counteract the effects of autoantibodies and alleviate the ME/CFS symptoms using a combination of already existing drugs, specific for each individual case.
Technical Summary
Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS) is a condition of extreme tiredness and brain fog, often triggered by an acute infection. Its prevalence is ca 0.9% and here is no effective treatment. Competing theories for the root cause of ME/CFS include metabolic or redox homeostasis disruption, and presence of autoantibodies (AABs) against G protein coupled receptors (GPCRs) involved in regulation of blood flow.
Triggered by acute infection, autoimmunity is a result of reduced immuno-vigilance during severe infections, when an "all hands on deck" approach confers survival advantage. About 30% of ME/CFS patients show increased titre of autoantibodies against beta2-adrenoceptor and M3/4 muscarinic receptors controlling vasodilation/vasoconstriction, but this could become higher if all 30 receptors controlling blood flow would be taken into account.
In this project, we will test a hypothesis that the pharmacological activity of AABs against GPCRs is the key to their involvement in ME/CFS. Similar to medical drugs, AABs can be stimulatory (agonistic) or inhibitory (antagonistic) and induce a therapeutic or an undesired side effect.
We will profile 325 patient samples and 130 control plasma samples for AABs and their pharmacological activity using a state-of-the art GPCR drug screening pipeline we have established, against all 30 GPCRs involved in blood pressure regulation. We also have machine learning expertise that would allow us to interpret this extensive dataset, extract the most salient features. This will advance the understanding of the molecular basis of ME/CFS and could form the basis of a robust diagnostic blood test for ME/CFS. Ultimately, our findings may point in the direction of developing combination therapy using repurposed drugs to counteract the effects of autoantibodies and mitigate ME/CFS symptoms and stimulate the development of specific B-cell elimination strategy to cure ME/CFS.
Triggered by acute infection, autoimmunity is a result of reduced immuno-vigilance during severe infections, when an "all hands on deck" approach confers survival advantage. About 30% of ME/CFS patients show increased titre of autoantibodies against beta2-adrenoceptor and M3/4 muscarinic receptors controlling vasodilation/vasoconstriction, but this could become higher if all 30 receptors controlling blood flow would be taken into account.
In this project, we will test a hypothesis that the pharmacological activity of AABs against GPCRs is the key to their involvement in ME/CFS. Similar to medical drugs, AABs can be stimulatory (agonistic) or inhibitory (antagonistic) and induce a therapeutic or an undesired side effect.
We will profile 325 patient samples and 130 control plasma samples for AABs and their pharmacological activity using a state-of-the art GPCR drug screening pipeline we have established, against all 30 GPCRs involved in blood pressure regulation. We also have machine learning expertise that would allow us to interpret this extensive dataset, extract the most salient features. This will advance the understanding of the molecular basis of ME/CFS and could form the basis of a robust diagnostic blood test for ME/CFS. Ultimately, our findings may point in the direction of developing combination therapy using repurposed drugs to counteract the effects of autoantibodies and mitigate ME/CFS symptoms and stimulate the development of specific B-cell elimination strategy to cure ME/CFS.
