Cellulose Structural Polymorphism in Plant Primary
Cell Walls Investigated by High-Field 2D Solid-State NMR Spectroscopy
and Density Functional Theory Calculations
posted on 2016-05-18, 00:00authored byTuo Wang, Hui Yang, James
D. Kubicki, Mei Hong
The native cellulose
of bacterial, algal, and animal origins has
been well studied structurally using X-ray and neutron diffraction
and solid-state NMR spectroscopy, and is known to consist of varying
proportions of two allomorphs, Iα and Iβ, which differ
in hydrogen bonding, chain packing, and local conformation. In comparison,
cellulose structure in plant primary cell walls is much less understood
because plant cellulose has lower crystallinity and extensive interactions
with matrix polysaccharides. Here we have combined two-dimensional
magic-angle-spinning (MAS) solid-state nuclear magnetic resonance
(solid-state NMR) spectroscopy at high magnetic fields with density
functional theory (DFT) calculations to obtain detailed information
about the structural polymorphism and spatial distributions of plant
primary-wall cellulose. 2D 13C–13C correlation
spectra of uniformly 13C-labeled cell walls of several
model plants resolved seven sets of cellulose chemical shifts. Among
these, five sets (denoted a–e) belong to cellulose
in the interior of the microfibril while two sets (f and g) can be assigned to surface cellulose. Importantly,
most of the interior cellulose 13C chemical shifts differ
significantly from the 13C chemical shifts of the Iα
and Iβ allomorphs, indicating that plant primary-wall cellulose
has different conformations, packing, and hydrogen bonding from celluloses
of other organisms. 2D 13C–13C correlation
experiments with long mixing times and with water polarization transfer
revealed the spatial distributions and matrix-polysaccharide interactions
of these cellulose structures. Celluloses f and g are well mixed chains on the microfibril surface, celluloses a and b are interior chains that are in
molecular contact with the surface chains, while cellulose c resides in the core of the microfibril, outside spin diffusion
contact with the surface. Interestingly, cellulose d, whose chemical shifts differ most significantly from those of bacterial,
algal, and animal cellulose, interacts with hemicellulose, is poorly
hydrated, and is targeted by the protein expansin during wall loosening.
To obtain information about the C6 hydroxymethyl conformation of these
plant celluloses, we carried out DFT calculations of 13C chemical shifts, using the Iα and Iβ crystal structures
as templates and varying the C5–C6 torsion angle. Comparison
with the experimental chemical shifts suggests that all interior cellulose
favor the tg conformation, but cellulose d also has a similar propensity to adopt the gt conformation. These results indicate that cellulose in plant primary
cell walls, due to their interactions with matrix polysaccharides,
and has polymorphic structures that are not a simple superposition
of the Iα and Iβ allomorphs, thus distinguishing them
from bacterial and animal celluloses.