Genetic Engineering of Functional Large Amyloid Fibers

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Date
2016-01-29
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Virginia Tech
Abstract

"Template" and "adder" proteins can be genetically encoded to produce large amyloid fibers when mixed together. Escherichia coli is used to clone a "template" protein, Gd20, which will cooperatively self-assemble with two "adder" proteins, P7Q and P7S, to yield two different large amyloid fibers. Atomic force microscopy (AFM) is used to image the fibers and AFM tip approach/retraction force is used to quantify molecular packing in the fibers. Glutamine (Q)-containing P7Q and serine (S)-containing P7S both have the same hydrophobic core, charge, and hydrogen bonding potential. However, P7Q is highly alpha-helical while P7S contains a beta-sheet core. After 72 hours, the Gd20:P7Q template:adder protein mixture produces tightly packed ~0.3 μm high and ~1.9 μm wide fibers that exhibit a low retraction force of ~44 nN after indentation. The Gd20:P7S mixture produces larger ~1.1 μm high and ~9.7 μm wide fibers exhibiting a much higher retraction force of ~503 nN showing they are much less molecularly packed. These results indicate that the adder protein alpha-helical character is important for self-assembly and molecular packing inside of the large amyloid fiber. The experimental results show that large amyloid fibers with predictable size and mechanical properties can be anticipated and encoded at the genetic level.

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Keywords
self-assembly, genetic encoding, fibril, fiber, amyloid, cellular expression, point spectroscopy, nanoindentation, molecular packing, retraction force, AFM
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