posted on 2017-03-14, 00:00authored byYoann Laurin, Joel Eyer, Charles H. Robert, Chantal Prevost, Sophie Sacquin-Mora
Although they play
a significant part in the regulation of microtubule
structure, dynamics, and function, the disordered C-terminal tails
of tubulin remain invisible to experimental structural methods and
do not appear in the crystallographic structures that are currently
available in the Protein Data Bank. Interestingly, these tails concentrate
most of the sequence variability between tubulin isotypes and are
the sites of the principal post-translational modifications undergone
by this protein. Using homology modeling, we developed two complete
models for the human αI/βI- and αI/βIII-tubulin
isotypes that include their C-terminal tails. We then investigated
the conformational variability of the two β-tails using long
time-scale classical molecular dynamics simulations that revealed
similar features, notably the unexpected presence of common anchoring
regions on the surface of the tuulin dimer, but also distinctive mobility
or interaction patterns, some of which could be related to the tail
lengths and charge distributions. We also observed in our simulations
that the C-terminal tail from the βI isotype, but not the βIII
isotype, formed contacts in the putative binding site of a recently
discovered peptide that disrupts microtubule formation in glioma cells.
Hindering the binding site in the βI isotype would be consistent
with this peptide’s preferential disruption of microtubule
formation in glioma, whose cells overexpress βIII, compared
to normal glial cells. While these observations need to be confirmed
with more intensive sampling, our study opens new perspectives for
the development of isotype-specific chemotherapy drugs.