![One of the activating molecules synthesized by the research group binds to Sirtuin 6. The chemical name of the activator is “4-(pyridine-3-yl)-4,5-dihydropyrrolo[1,2-α]quinoxaline”. Illustration: Clemens Steegborn (free with attribution).](https://infowebbie.com/scienceupdate/wp-content/uploads/2017/03/Small-molecules-fighting-aging-related-diseases-New-findings-in-sirtuin-researc_2017-03-07_16-08-22.png)
One of the activating molecules synthesized by the research group binds to Sirtuin 6. The chemical name of the activator is “4-(pyridine-3-yl)-4,5-dihydropyrrolo[1,2-α]quinoxaline”. Illustration: Clemens Steegborn (free with attribution).
Up to now only activators for Sirt1 were known. In close collaboration with scientists at Martin Luther University Halle-Wittenberg, Sapienza University of Rome (Italy), and Stanford University (CA, USA), the research group led by Prof. Clemens Steegborn at University of Bayreuth has now succeeded in developing selective Sirt6 activators as well. These small molecules dock specifically on Sirt6, thus increasing the activity of this enzyme. It catalyzes the removal of acetyl groups, eg from nucleosomes, which modulate the activity of genes.
“Sirt6 has a unique channel, which leads from the surface of the enzyme to its catalytic center and features a binding pocket that is easily accessible from the outside. Thereby, all structural requirements are fulfilled for efficient docking of the small activators into this pocket. With a few exceptions, these small molecule activators are unable to attach to other Sirtuins, which means they are specific for Sirt6” Prof. Steegborn explains. “Our new insights offer a very promising starting point for the development of targeted compounds. These would enable further biomedical research, and they might also support therapeutic measures, e.g. in the fight against tumors,” he says.
The activating molecules for Sirt6 are compounds based on pyrrolo[1,2-α]quinoxaline. A total of 14 compound variations were used by the researchers. The molecules displayed considerably differing effects on Sirt6. Some substances activated Sirt6-dependent removal of acetyl groups; other substances were limited in their effect to suppressing a different activity of the enzyme. Based on these discoveries one can imagine that one day it will not only be possible to activate Sirt6 in a targeted way, but even to achieve a more precise “fine-tuning” of the metabolic processes it regulates. “The compounds we developed and the new findings on their interaction with Sirt6 provide a unique basis for the rational design of further refined molecules. Now that we have succeeded in revealing the structural details of this interaction, we are finally in a position to modulate the enzyme sirtuin 6 very specifically with drugs,” Prof. Steegborn explained.
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