Molecular basis of the evolution of new protein functions: Kemp elimination and phosphoryl transfer reactions
Date
2016
Authors
Hong, Nan-Sook
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Abstract
This is a series of investigations into the molecular basis
of the evolution of new protein functions. The broad objective of
this work was to determine exactly how a series of single amino
acid mutations, typical of an evolutionary trajectory, can result
in dramatic changes in catalytic activity, specificity and
protein solubility. Various strategies were employed to achieve
this aim, including analysis of existing literature concerning
the various models and theories relating to molecular evolution,
protein crystallography, extensive enzyme kinetics and
thermodynamic analysis, theoretical analysis of catalytic
mechanisms and computational simulation of protein dynamics.
Three model systems were investigated: the de novo designed Kemp
Eliminase (KE07), the metallo-beta-lactamases NDM1 and VIM2, and
the N-acyl-homoserine lactonase AiiA. Based on these studies, I
was able to identify three clear phenomena that are important in
molecular evolution: first, preorganization of the active sites
residues is essential for efficient catalysis; second, remote
mutations are capable of causing quite drastic rearrangements to
the active site and substrate binding site by modulating the
conformational landscape of a protein; third, intramolecular
epistasis, the way that mutations interact with each other and
the sequence background that they are introduced to, can
constrain evolutionary trajectories and make the evolutionary
potential of a protein contingent on its starting sequence.
In Chapters 3-5 I focus on KE07, performing detailed
kinetic analysis of hydrogenated and deuterated substrate, which
revealed entropy-enthalpy compensation in the improvement in
activity as well as an unusual change in the kinetic properties
in the middle of the evolutionary trajectory. This is followed by
comprehensive structural analysis, which reveals the enzyme has
evolved to adopt a completely unexpected active site
configuration via remote mutations. Finally, using computational
simulations and solution fluorescence spectroscopy, I confirm
that the in crystallo and kinetic observations are consistent
with the behaviour of the protein in solution. Chapter 6 consists
of a manuscript that describes the effects of conformational
tinkering on the N-acyl-homoserine lactonase AiiA, specifically
how remote mutations can have dramatic effects on activity by
modulating the conformation of the active site. My contribution
to this work included crystal structures and molecular dynamics
simulations. Finally, Chapter 7 is a second manuscript that
focuses on evolutionary contingency: by examining two related
sub-families of the metallo-beta-lactamases, NDM1 and VIM2 we
show that the evolvability of each is constrained by
intramolecular epistasis and contingent on the starting sequence.
To achieve the same final goal (greater whole cell activity),
NDM1 evolved higher activity, while VIM2 evolved greater
solubility. The crystals structures that I solved revealed the
structural basis for the enhanced activity in NDM1 and that
enhanced solubility in VIM2 is a result of an unprecedented (for
an enzyme) structural rearrangement where the two halves of the
alpha/beta sandwich metallo-beta-lactamase protein fold have
separated and rearranged in an domain-swapped dimer.
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Kemp eliminase, Phosphoryl transfer, Kinetic isotope effect, enzyme evolution, protein structure and function
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Thesis (PhD)
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