Intracellular microtubules can bear large compressive loads
classical buckling of elastic rods in and elastic continuum
Cytoskeletal microtubules have been proposed to influence cell
shape and mechanics based on their ability to resist large-scale compressive
forces exerted by the surrounding contractile cytoskeleton. Consistent with
this, cytoplasmic microtubules are often highly curved and appear buckled
because of compressive loads. However, the results of in vitro studies suggest
that microtubules should buckle at much larger length scales, withstanding only
exceedingly small compressive forces. This discrepancy calls into question the
structural role of microtubules, and highlights our lack of quantitative
knowledge of the magnitude of the forces they experience and can withstand in
living cells. We show that intracellular microtubules do bear large-scale
compressive loads from a variety of physiological forces, but their buckling
wavelength is reduced significantly because of mechanical coupling to the
surrounding elastic cytoskeleton. We quantitatively explain this behavior, and
show that this coupling dramatically increases the compressive forces that
microtubules can sustain, suggesting they can make a more significant structural
contribution to the mechanical behavior of the cell than previously thought
possible.
Cytoskeletal microtubules have been proposed to influence cell
shape and mechanics based on their ability to resist large-scale compressive
forces exerted by the surrounding contractile cytoskeleton. Consistent with
this, cytoplasmic microtubules are often highly curved and appear buckled
because of compressive loads. However, the results of in vitro studies suggest
that microtubules should buckle at much larger length scales, withstanding only
exceedingly small compressive forces. This discrepancy calls into question the
structural role of microtubules, and highlights our lack of quantitative
knowledge of the magnitude of the forces they experience and can withstand in
living cells. We show that intracellular microtubules do bear large-scale
compressive loads from a variety of physiological forces, but their buckling
wavelength is reduced significantly because of mechanical coupling to the
surrounding elastic cytoskeleton. We quantitatively explain this behavior, and
show that this coupling dramatically increases the compressive forces that
microtubules can sustain, suggesting they can make a more significant structural
contribution to the mechanical behavior of the cell than previously thought
possible.