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The effect of leaving group on mechanistic preference in phosphate monoester hydrolysis

Kamerlin, Shina C L LU orcid and Wilkie, John (2011) In Organic and Biomolecular Chemistry 9(15). p.406-5394
Abstract

We present 2-dimensional potential energy surfaces and optimised transition states (TS) for water attack on a series of substituted phosphate monoester monoanions at the DFT level of theory, comparing a standard 6-31++g(d,p) basis set with a larger triple-zeta (augmented cc-pVTZ) basis set. Small fluorinated model compounds are used to simulate increasing leaving group stability without adding further geometrical complexity to the system. We demonstrate that whilst changing the leaving group causes little qualitative change in the potential energy surfaces (with the exception of the system with the most electron withdrawing leaving group, CF(3)O(-), in which the associative pathway changes from a stepwise A(N) + D(N) pathway to a... (More)

We present 2-dimensional potential energy surfaces and optimised transition states (TS) for water attack on a series of substituted phosphate monoester monoanions at the DFT level of theory, comparing a standard 6-31++g(d,p) basis set with a larger triple-zeta (augmented cc-pVTZ) basis set. Small fluorinated model compounds are used to simulate increasing leaving group stability without adding further geometrical complexity to the system. We demonstrate that whilst changing the leaving group causes little qualitative change in the potential energy surfaces (with the exception of the system with the most electron withdrawing leaving group, CF(3)O(-), in which the associative pathway changes from a stepwise A(N) + D(N) pathway to a concerted A(N)D(N) pathway), there is a quantitative change in relative gas-phase and solution barriers for the two competing pathways. In line with previous studies, in the case of OCH(3), the barriers for the associative and dissociative pathways are similar in solution, and the two pathways are equally viable and indistinguishable in solution. However, significantly increasing the stability of the leaving group (decreasing proton affinity, PA) results in the progressive favouring of a stepwise dissociative, D(N) + A(N), mechanism over associative mechanisms.

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author
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publishing date
type
Contribution to journal
publication status
published
keywords
Hydrolysis, Molecular Structure, Organophosphates/chemistry, Phosphates/chemistry, Quantum Theory, Thermodynamics
in
Organic and Biomolecular Chemistry
volume
9
issue
15
pages
13 pages
publisher
Royal Society of Chemistry
external identifiers
  • pmid:21655563
  • scopus:79960343589
ISSN
1477-0539
DOI
10.1039/c0ob01210f
language
English
LU publication?
no
id
f2f70a2a-21ad-41b5-9f7b-390dde45de5e
date added to LUP
2025-01-11 22:10:24
date last changed
2025-01-23 03:22:05
@article{f2f70a2a-21ad-41b5-9f7b-390dde45de5e,
  abstract     = {{<p>We present 2-dimensional potential energy surfaces and optimised transition states (TS) for water attack on a series of substituted phosphate monoester monoanions at the DFT level of theory, comparing a standard 6-31++g(d,p) basis set with a larger triple-zeta (augmented cc-pVTZ) basis set. Small fluorinated model compounds are used to simulate increasing leaving group stability without adding further geometrical complexity to the system. We demonstrate that whilst changing the leaving group causes little qualitative change in the potential energy surfaces (with the exception of the system with the most electron withdrawing leaving group, CF(3)O(-), in which the associative pathway changes from a stepwise A(N) + D(N) pathway to a concerted A(N)D(N) pathway), there is a quantitative change in relative gas-phase and solution barriers for the two competing pathways. In line with previous studies, in the case of OCH(3), the barriers for the associative and dissociative pathways are similar in solution, and the two pathways are equally viable and indistinguishable in solution. However, significantly increasing the stability of the leaving group (decreasing proton affinity, PA) results in the progressive favouring of a stepwise dissociative, D(N) + A(N), mechanism over associative mechanisms.</p>}},
  author       = {{Kamerlin, Shina C L and Wilkie, John}},
  issn         = {{1477-0539}},
  keywords     = {{Hydrolysis; Molecular Structure; Organophosphates/chemistry; Phosphates/chemistry; Quantum Theory; Thermodynamics}},
  language     = {{eng}},
  month        = {{08}},
  number       = {{15}},
  pages        = {{406--5394}},
  publisher    = {{Royal Society of Chemistry}},
  series       = {{Organic and Biomolecular Chemistry}},
  title        = {{The effect of leaving group on mechanistic preference in phosphate monoester hydrolysis}},
  url          = {{http://dx.doi.org/10.1039/c0ob01210f}},
  doi          = {{10.1039/c0ob01210f}},
  volume       = {{9}},
  year         = {{2011}},
}