Hymecromone can suppress neuroinflammation in astrocytes, study shows
Posted: 1 March 2021 | Victoria Rees (Drug Target Review) | No comments yet
Researchers have found that the spasmolytic drug hymecromone can suppress astrocyte inflammatory responses, meaning it could be used to combat Alzheimer’s disease.
Biologists have confirmed that a well-known spasmolytic drug called hymecromone can suppress the inflammatory response in astrocytes, important glial cells of the central nervous system (CNS). They say it could be used to develop medications against Alzheimer’s disease and other neurodegenerative conditions. The study was conducted at the Peoples’ Friendship University of Russia (RUDN University).
According to the researchers, when inflamed, astrocytes produce many anti-inflammatory molecules (cytokines, interleukins and oxylipins) that aggravate and speed up the inflammatory process.
The team confirmed that the intensity of inflammation can be reduced by limiting the number of anti-inflammatory molecules produced by astrocytes. To do so, they suggest using hymecromone, a drug that is currently used to treat spasms.
“Astrocytes can synthesise hyaluronic acid, one of the main components of the brain’s extracellular matrix. Our studies demonstrated that when hyaluronic acid is added to the astrocytes, it affects the production of the main anti-inflammatory molecules. In this work, we tested hymecromone that suppresses the synthesis of hyaluronic acid and measured its effect on the inflammatory response of astrocytes,” said Dr Dmitry Chistyakov, a senior researcher at RUDN University.
The team studied the effect of hymecromone on astrocytes in a rat brain cell culture. Cell culture samples were treated with a liposaccharide that activated the receptors in charge of the inflammation and then with hymecromone. In order to assess the efficiency of the drug, the team extracted RNA from astrocytes and measured the activity of the genes that regulate the production of the anti-inflammatory molecules. The levels of hyaluronic acid and cytokines were measured in cell supernatants. The changes in the synthesis of signal lipids (oxylipins) were evaluated using the methods of high-efficiency liquid chromatography and tandem mass spectrometry.
Hymecromone turned out to suppress the production of anti-inflammatory molecules: tumour necrosis factor α and interleukins IL-6 and IL-1β, as well as oxylipins. At the same time, it increased the development of IL-10 that helps stop the inflammation. Having measured the levels of hyaluronic acid, the team confirmed that astrocytes actively produced this substance in response to liposaccharides. However, when a cell culture at the initial stages of the immune response was treated with hymecromone, the levels of hyaluronic acid dropped down. At the same time, hymecromone failed to have the same effect on the cells that did not inflame after contact with the liposaccharide. In these cultures, astrocytes continued to produce hyaluronic acid in regular quantities.
According to the biologists, it is still early to say for sure that the anti-inflammatory properties of hymecromone are rooted in its ability to reduce the production of hyaluronic acid. Still, the team is positive that these processes are connected.
“We managed to confirm that hymecromone is a promising compound that can be used to treat neuroinflammation. The mechanisms of its anti-inflammatory activity require further studies but given that this drug is widely used in clinical practice, the possibilities of such research are vast. Its efficiency can be safely tested when treating many pathologies that require inflammatory response suppression,” added Chistyakov.
The study was published in the International Journal of Molecular Sciences.
Related topics
Cell culture, CNS, Lipidomics, Mass Spectrometry, Neuroprotection, Neurosciences
Related conditions
Alzheimer's disease (AD)
Related organisations
Peoples' Friendship University of Russia (RUDN University)
Related people
Dr Dmitry Chistyakov