Structural Basis for Reduced Dynamics of Three Engineered
HNH Endonuclease Lys-to-Ala Mutants for the Clustered Regularly Interspaced
Short Palindromic Repeat (CRISPR)-Associated 9 (CRISPR/Cas9) Enzyme
posted on 2022-04-14, 18:11authored byJimin Wang, Erin Skeens, Pablo R. Arantes, Federica Maschietto, Brandon Allen, Gregory W. Kyro, George P. Lisi, Giulia Palermo, Victor S. Batista
Many
bacteria possess type-II immunity against invading phages
or plasmids known as the clustered regularly interspaced short palindromic
repeat (CRISPR)/CRISPR-associated 9 (Cas9) system to detect and degrade
the foreign DNA sequences. The Cas9 protein has two endonucleases
responsible for double-strand breaks (the HNH domain for cleaving
the target strand of DNA duplexes and RuvC domain for the nontarget
strand, respectively) and a single-guide RNA-binding domain where
the RNA and target DNA strands are base-paired. Three engineered single
Lys-to-Ala HNH mutants (K810A, K848A, and K855A) exhibit an enhanced
substrate specificity for cleavage of the target DNA strand. We report
in this study that in the wild-type (wt) enzyme, D835, Y836, and D837
within the Y836-containing loop (comprising E827-D837) adjacent to
the catalytic site have uncharacterizable broadened 1H15N nuclear magnetic resonance (NMR) features, whereas remaining
residues in the loop have different extents of broadened NMR spectra.
We find that this loop in the wt enzyme exhibits three distinct conformations
over the duration of the molecular dynamics simulations, whereas the
three Lys-to-Ala mutants retain only one conformation. The versatility
of multiple alternate conformations of this loop in the wt enzyme
could help to recruit noncognate DNA substrates into the HNH active
site for cleavage, thereby reducing its substrate specificity relative
to the three mutants. Our study provides further experimental and
computational evidence that Lys-to-Ala substitutions reduce dynamics
of proteins and thus increase their stability.