Proton tunnelling in ribosomal peptide bond formation / Hadieh Monajemi
Proton transfer reactions are simple yet important reactions which have been immensely investigated in different studies due to their dominance in many chemical and biochemical systems. The dual wave-particle nature of protons enables them to tunnel through classically high potential energy barri...
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| Format: | Thesis |
| Published: |
2018
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| Online Access: | http://studentsrepo.um.edu.my/12338/1/Hadieh.pdf http://studentsrepo.um.edu.my/12338/2/Hadieh_Monajemi.pdf http://studentsrepo.um.edu.my/12338/ |
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| Summary: | Proton transfer reactions are simple yet important reactions which have been immensely
investigated in different studies due to their dominance in many chemical and
biochemical systems. The dual wave-particle nature of protons enables them to tunnel
through classically high potential energy barriers. Being temperature independent,
proton tunnelling can occur at any temperature. Hence, many studies have suggested
that some enzymatic reactions with high energy barriers go through proton tunnelling.
However, the occurrence of tunnelling has not yet been investigated in one of the most
puzzling enzymatic reactions, i.e. the process of peptide bond formation in a large
complex enzyme called the ribosome. A large part of this study aims to investigate the
tunnelling behaviour in this mechanism using computational quantum chemistry tools
and theoretical methods. We proposed three novel proton transfer mechanisms for this
reaction which are based on three different crystallographic structures. Using density
functional theory, we first obtained the structural and physical information about these
reaction mechanisms. The rate of these reactions were then calculated using reaction
rate theories with classical motion approximation. Ultimately, the tunnelling correction
was calculated numerically and added to the classical reaction rate to investigate the
tunnelling behaviour of proton. The results show that in one of our novel proposed
mechanisms, the ribosome induces tunnelling by thinning the energy barrier width
through shortening the proton donor-acceptor distance. This explains the unexpectedly
high rate of ribosomal peptide bond formation. Using this idea, we attempted to induce
tunnelling in a synthetic reaction and increase its efficiency. For this purpose, we
studied the reaction of boronic acid with diols which is important in designing an
efficient non-enzymatic glucose sensor for blood glucose monitoring applications. The results indicate that one way to induce tunnelling through decreasing the donor-acceptor
distance is to increase the electronegativity of the R-group. The transition structure for
the highest electronegative R-group exhibits the shortest proton path from boronic acid
to diol. The direct correlation of the electronegativity and the tunnelling corrected
reaction rate further supports the importance of the lower donor-acceptor distance in
inducing tunnelling.
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