Study identifies key enzyme for development of autoimmune diseases
October 21, 2020
By Maria Fernanda Ziegler | Agência FAPESP – Scientists affiliated with the Center for Research on Inflammatory Diseases (CRID), hosted by the University of São Paulo (USP) in Brazil, have discovered that an enzyme involved in key metabolic processes also plays a role in immune cell differentiation and hence in the development of autoimmune diseases. The finding could contribute to the future development of new treatments and more cost-effective and resolutive medications for this kind of disease.
The study is reported in the Journal of Experimental Medicine. The article describes the role of PKM2 (pyruvate kinase M2), the enzyme responsible for the final step of glycolysis, in the development and maintenance of the exacerbated inflammation typical of autoimmune diseases. Glycolysis is the breakdown of glucose to extract energy for cellular metabolism.
“We demonstrated in the study that there’s a link between cellular metabolism and the immune system. It’s increasingly clear that enzymes and other metabolic molecules are important not just to cellular metabolism but also to other functions such as immune response. In this particular case we found that the enzyme PKM2 acts in parallel with the differentiation of Th17, a lymphocyte subtype that triggers experimental autoimmune encephalomyelitis, an animal model of multiple sclerosis,” said José Carlos Farias Alves Filho, a researcher at CRID, which is one of several Research, Innovation and Dissemination Centers (RIDCs) supported by FAPESP. CRID is hosted by USP’s Ribeirão Preto Medical School (FMRP-USP).
T helper lymphocytes
In order to neutralize different pathogens specifically, immune cells called T lymphocytes differentiate into an array of subtypes, including T helper type 17 cells (Th17). These are associated with the development and maintenance of inflammation common to autoimmune diseases.
For poorly understood reasons, in autoimmune diseases such as multiple sclerosis, arthritis, and psoriasis, the immune response can spiral out of control and lead T lymphocytes to attack their own organism as if it were a pathogen.
For his project, Damasceno used the model known as experimental immune encephalomyelitis, an inflammatory demyelinating disease of the central nervous system that causes loss of the myelin sheath protecting nerve fibers and allowing electrical impulses to transmit quickly and efficiently along them. The experimental model closely resembles the condition of patients with multiple sclerosis.
Th17 cells have long been known to play a key role in mediating the development of autoimmune disease and progression of the neuroinflammation typical of several autoimmune disorders. The initial auto-reactive response that triggers the disease occurs when Th17 cells mistake antigens present in the central nervous system for a threat, releasing large amounts of a pro-inflammatory protein called interleukin 17 (IL-17) into spinal cord and brain tissue lesions.
In the study, which used cultured cells and the animal model, the CRID researchers found that differentiation of T lymphocytes into Th17 cells and development of the disease depended on metabolic reprogramming and alterations in glycolysis. “The glycolytic enzyme pyruvate kinase M2 [PKM2] mediated Th17 differentiation and autoimmune inflammation,” Alves Filho said. “We showed in the study that significant amounts of the enzyme are expressed during differentiation of T lymphocytes into Th17 cells.”
When PKM2 specific to T cells was excluded in vitro, Th17 differentiation was impaired and symptoms of the disease were attenuated, reducing the inflammation and demyelination mediated by Th17. “In the tests involving mice modified not to express the enzyme, development of the disease was reduced by over 50%,” Alves Filho said.
The researchers also analyzed the use of commercial drugs that inhibit PKM2. “We used a drug that inhibits nuclear translocation of PKM2 so that the enzyme doesn’t reach the cell nucleus. The lymphocytes express the enzyme, but it doesn’t influence the development of the disease. It’s reduced because Th17 differentiation decreases,” he said.
Costs and benefits of treatment
The discovery of PKM2’s role in autoimmune diseases paves the way for the development of novel strategies to treat them. The immunosuppressants currently available on the market treat these diseases by inhibiting the cytokines that help activate and differentiate the various lymphocyte subtypes.
“An estimated 40% of patients don’t respond well to these drugs for one reason or another,” Alves Filho said. “They could be put on immunobiological drugs, which are highly beneficial but extremely expensive and unaffordable for many patients.”
The enzyme is part of CRID’s drug discovery platform. “In the study we used a commercial drug that targets an allosteric site of PKM2, blocking the enzyme’s ability to translocate to the Th17 cell nucleus,” he said. A new study has begun, in collaboration with the Biosciences National Laboratory (LNBio) at the Brazilian Center for Research in Energy and Materials (CNPEM) in Campinas, state of São Paulo, to develop drugs that target translocation of the enzyme.
“This opens up the prospect of novel treatments for autoimmune diseases or inflammatory diseases that depend on this enzyme,” Alves Filho said. “In this next stage, we’re aiming to develop drugs that interact with this site and inhibit the enzyme’s ability to translocate to the cell nucleus.”
The article “PKM2 promotes Th17 cell differentiation and autoimmune inflammation by fine-tuning STAT3 activation” can be read at: rupress.org/jem/article/217/10/e20190613/151965/PKM2-promotes-Th17-cell-differentiation-and.
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