Mutant Plant Viruses with
Cell Binding Motifs Provide
Differential Adhesion Strengths and Morphologies
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Abstract
The ability of Tobacco mosaic virus
(TMV) to tolerate various amino acid insertions near its carboxy terminus
is well-known. Typically these inserts are based on antigenic sequences
for vaccine development with plant viruses as carriers. However, we
determined that the structural symmetries and the size range of the
viruses could also be modeled to mimic the extracellular matrix proteins
by inserting cell-binding sequences to the virus coat protein. The
extracellular matrix proteins play important roles in guiding cell
adhesion, migration, proliferation, and stem cell differentiation.
Previous studies with TMV demonstrated that the native and phosphate-modified
virus particles enhanced stem cell differentiation toward bone-like
tissues. Based on these studies, we sought to design and screen multiple
genetically modified TMV mutants with reported cell adhesion sequences
to expand the virus-based tools for cell studies. Here, we report
the design of these mutants with cell binding amino acid motifs derived
from several proteins, the stabilities of the mutants against proteases
during purification and storage, and a simple and rapid functional
assay to quantitatively determine adhesion strengths by centrifugal
adhesion assay. Among the mutants, we found that cells on TMV expressing
RGD motifs formed filopodial extensions with weaker attachment profiles,
whereas the cells on TMV expressing collagen I mimetic sequence displayed
little spreading but higher attachment strengths