Protein Discovered that Protects Against Fatty Liver
A team of scientists at the Institute for Research in Biomedicine and the IDIBAPS Biomedical Research Institute has revealed the capacity of the CPEB4 protein to prevent fatty liver disease.
Non-alcoholic fatty liver is characterised by the accumulation of fat deposits in hepatocytes. The development of this condition is determined by many factors that have not been well described to date. However, obesity and lifestyle, as well as aging, are associated with an increase in the incidence of this disease. Also, a number of large-scale genomics studies have linked variants of the CPEB4 gene with the impairment of fat metabolism.
The scientists at IRB Barcelona depleted CPEB4 expression in mouse livers in order to study the function of this protein. They observed that the mice developed fatty liver as they aged. Furthermore, young CPEB4-depleted mice fed a high-fat diet also developed this condition in a more pronounced manner. Carlos Maíllo, first author of the article and PhD student at IRB Barcelona has described the molecular function of CPEB4. He reveals that this protein is essential to drive the liver stress response.
Specifically, under stress, caused by uncontrolled ingestion of fats for example, the endoplasmic reticulum, a cell organelle associated with protein synthesis and folding and lipid metabolism, stops its activity in order to re-establish cell equilibrium. This “clean-up” mechanism is orchestrated by CPEB4 and varies in function of the time of day, being more active in humans during the day and dropping off at night. Without CPEB4, the endoplasmic reticulum is unable to activate the stress response, thus causing hepatocytes to accumulate the lipids produced by the fatty liver.
Raúl Méndez, ICREA researcher at IRB Barcelona and co-leader of the study, explains that “knowledge of the hepatic function of CPEB4 could be useful as a predictive marker for those people with variants of this protein, thus serving to prevent this condition, for example, through improvements in diet and better choice of eating times. Such knowledge could also contribute to the development of treatments that boost the clean-up process”.
The researchers have managed to reverse fatty liver disease in mice by treatment with a drug called Tudca, which is currently used for other disorders. This drug exerts the same function as the proteins that are activated by CPEB4 and that are responsible for cleaning up the cell, namely chaperones. “In the future it may be possible to design molecules like Tudca that specifically target CPEB4, thus enhancing the liver clean-up process,” proposes Méndez.
“This basic research study does not have a direct and immediate clinical application, but it lays down the foundation for the applied science that follows,” says Mercedes Fernández, co-leader of the study and head of the group at IDIBAPS and the Biomedical Research Networking Center of Hepatic and Digestive Diseases (CIBEREHD).
Fernández warns, “Given the obesity epidemic in the US and worldwide, an increase in those affected by non-alcoholic fatty liver disease is expected in the coming decades and we still do not have a suitable treatment for this condition; A fundamental understanding of this medical problem is therefore essential for development of novel treatment strategies.”
It is estimated that between 80 and 100 million people in the US alone suffer from fatty liver disease. People with this disease have an increased risk of cirrhosis and liver cancer. Moreover, liver cancer incidence has more than tripled since 1980 and is the primary cause of death in patients with cirrhosis.
Maillo, C., Martín, J., Sebastián, D., Hernández-Alvarez, M., García-Rocha, M., Reina, O., Méndez, R. (2017). Circadian- and UPR-dependent control of CPEB4 mediates a translational response to counteract hepatic steatosis under ER stress. Nature Cell Biology. doi:10.1038/ncb3461
This article has been republished from materials provided by IRB Barcelona. Note: material may have been edited for length and content. For further information, please contact the cited source.
Scientists have developed a way to identify the beginning of every gene — known as a translation start site or a start codon — in bacterial cell DNA with a single experiment and, through this method, they have shown that an individual gene is capable of coding for more than one protein.