Helminth derivative tuftsin-phopshorylcholine to treat autoimmunity

Autoimmune diseases (AIDs) affect 5 to 10% of the population. There are more than ∼100 different autoimmune diseases. The AIDs are one of the top 10 causes of death in women under 65; 2nd highest cause of chronic illness; top cause of morbidity in women in the US. The NIH estimates annual direct healthcare costs for autoimmune diseases about $100 billion, in comparison, with cancers investment of $57 billion, heart and stroke cost of $200 billion. The current treatments for autoimmune diseases encompasses: steroids, chemotherapy, immunosuppressants, biological drugs, disease specific drugs (like acethylcholine-estherase for myasthenia gravis). The treatments for autooimmune diseases supress the patient immune network, which leads the patients to be more susceptible to infections. Hence, there is a need to develop immunomodulatory small molecules with minimal side effects to treat autoimmune diseases. The helminths developed secreting compounds which modulate the human defense pathways in order to develop tolerance and survive in the host environment. We have imitated the immunomodulatory activity of the helminth by using a derivative of the helminth secretory molecule. A bi-functional small molecule –tuftsin (T)-phosphorylcholine (PC), coined as TPC, was constructed. This chimeric molecule showed its immunomodulatory activity in 4 murine models of autoimmune diseases, attenuating the clinical score and the inflammatory response by immunomodutating the host immune system. Ex-vivo in human peripheral blood mononuclear cells (PBMCs) and biopsies originated from arteries of patients with giant cell arteritis. This paper decipher the mode of action of TPC immunomodulatory activity. Our data propose the potential for this small molecule to be a novel therapy for patients with autoimmune diseases.