01:20am Tuesday 30 May 2017

The deadly toxin acrolein has a useful biological role

Schematic

Schematic of the findings

 

“What is remarkable, says Ayumi Tsutsui, the lead author of the paper published on June 1 in Advanced Science, “is that the reaction involves acrolein and a class of substances known as polyamines, which are all associated with oxidative stress. Polyamines are known to play very important biological roles, but the mechanisms are still poorly understood.” Levels of acrolein have been found to correlate with the progression of diseases such as cancer and stroke.” According to Tamotsu Zako of Ehime University, who participated in the research, “It made sense to see acrolein simply as a dangerous substance that triggers disease, and many researchers saw it that way. But in our previous work we had discovered that acrolein could bind with polyamines such as spermine and spermidine to form eight-atom cyclic molecules, and we wondered what biological role these rings might play.”

As the team began the experiments, they were surprised to find that these substances made from a combination of acrolein and the polyamines seemed to prevent the peptides known as amyloid-beta from aggregating together—a process linked to the progression of Alzheimer’s disease, where neurons are gradually killed by the accumulation of these amyloid peptides.

The group tested the hypothesis by incubating Aβ40 peptides in mixtures of acrolein, a polyamine known as spermine, and a cyclic compound formed by acrolein and polyamines. Neither of the first two molecules alone had any effect on fibrillation, but the cyclic compounds turned out to be powerful inhibitors. The researchers also found that when acrolein and polyamines were added together into a living cell, they combined naturally through 4+4 cycloaddition to create the diazacylooctane molecule.

According to Katsunori Tanaka, who led the team, “This is important for several reasons. First, it gives us insights into the mechanism through which polyamines—which we know to be tremendously important biologically—exert their action. And secondly, because acrolein and polyamines combine naturally in cells to form these powerful anti-fibrillation substances, it may open the way for us to influence the progression of terrible neurological disorders such as Alzheimer’s.”

Tanaka said that in the current experiment the group used Aβ40, an amyloid peptide with 40 amino acids in the chain, but that they also hope in the future to conduct experiments with Aβ42, which is more prone to fibrillation and is also believed to play a key role in Alzheimer’s disease.

Reference
•Ayumi Tsutsui, Tamotsu Zako, Tong Bu, Yoshiki Yamaguchi, Mizuo Maeda and Katsunori Tanaka, “1,5-Diazacyclooctanes, as Exclusive Oxidative Polyamine Metabolites, Inhibit Amyloid-β(1-40) Fibrillization”, Advanced Science

Contact

Associate Chief Scientist
 Katsunori Tanaka
Biofunctional Synthetic Chemistry Laboratory
Associate Chief Scientist Laboratories

Jens Wilkinson
 RIKEN Global Relations and Research Coordination Office
 Tel: +81-(0)48-462-1225 / Fax: +81-(0)48-463-3687
 Email: pr@riken.jp


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