Journal
FEBS JOURNAL
Volume 287, Issue 3, Pages 546-560Publisher
WILEY
DOI: 10.1111/febs.15046
Keywords
amyloid; crystal structure; molecular dynamics; protein aggregation; structural biology
Categories
Funding
- CINECA award under the ISCRA initiative
- Fondazione Cariplo [2016-0489]
- Fondazione ARISLA [TDP-43-STRUCT]
- Fondazione Telethon [GGP17036 2017]
- Borysiewicz Fellowship from the University of Cambridge
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The molecular bases of amyloid aggregation propensity are still poorly understood, especially for proteins that display a stable folded native structure. A prototypic example is human beta-2 microglobulin (beta 2m), which, when accumulated in patients, gives rise to dialysis-related amyloidosis. Interestingly, although the physiologic concentration of beta 2m in mice is five times higher than that found in human patients, no amyloid deposits are observed in mice. Moreover, murine beta 2m (m beta 2m) not only displays a lower amyloid propensity both in vivo and in vitro but also inhibits the aggregation of human beta 2m in vitro. Here, we compared human and m beta 2m for their aggregation propensity, ability to form soluble oligomers, stability, three-dimensional structure and dynamics. Our results indicate that m beta 2m low-aggregation propensity is due to two concomitant aspects: the low-aggregation propensity of its primary sequence combined with the absence of high-energy amyloid-competent conformations under native conditions. The identification of the specific properties determining the low-aggregation propensity of mouse beta 2m will help delineate the molecular risk factors which cause a folded protein to aggregate.
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