posted on 2023-02-03, 14:06authored byKosuke Kikuchi, Koki Date, Takafumi Ueno
Design and control of processes for a hierarchical assembly
of
proteins remain challenging because it requires consideration of design
principles with atomic-level accuracy. Previous studies have adopted
symmetry-based strategies to minimize the complexity of protein–protein
interactions and this has placed constraints on the structures of
the resulting protein assemblies. In the present work, we used an
anisotropic-shaped protein needle, gene product 5 (gp5) from bacteriophage
T4 with a C-terminal hexahistidine-tag (His-tag) (gp5_CHis), to construct
a hierarchical assembly with two distinct protein–protein interaction
sites. High-speed atomic force microscopy (HS-AFM) measurements reveal
that it forms unique tetrameric clusters through its N-terminal head
on a mica surface. The clusters further self-assemble into a monolayer
through the C-terminal His-tag. The HS-AFM images and displacement
analyses show that the monolayer is a network-like structure rather
than a crystalline lattice. Our results expand the toolbox for constructing
hierarchical protein assemblies based on structural anisotropy.