posted on 2021-03-30, 15:06authored byBrandon
H. Bowser, Shu Wang, Tatiana B. Kouznetsova, Haley K. Beech, Bradley D. Olsen, Michael Rubinstein, Stephen L. Craig
Mechanochemical
reactions that lead to an increase in polymer contour
length have the potential to serve as covalent synthetic mimics of
the mechanical unfolding of noncovalent “stored length”
domains in structural proteins. Here we report the force-dependent
kinetics of stored length release in a family of covalent domain polymers
based on cis-1,2-substituted cyclobutane mechanophores.
The stored length is determined by the size (n) of
a fused ring in an [n.2.0] bicyclic architecture,
and it can be made sufficiently large (>3 nm per event) that individual
unravelling events are resolved in both constant-velocity and constant-force
single-molecule force spectroscopy (SMFS) experiments. Replacing a
methylene in the pulling attachment with a phenyl group drops the
force necessary to achieve rate constants of 1 s–1 from ca. 1970 pN (dialkyl handles) to 630 pN (diaryl handles), and
the substituent effect is attributed to a combination of electronic
stabilization and mechanical leverage effects. In contrast, the kinetics
are negligibly perturbed by changes in the amount of stored length.
The independent control of unravelling force and extension holds promise
as a probe of molecular behavior in polymer networks and for optimizing
the behaviors of materials made from covalent domain polymers.