Despite the numerous experimental and theoretical studies on phosphate monoester hydrolysis, significant questions remain concerning the mechanistic details of these biologically critical reactions. In the present work we construct a linear free energy relationship for phosphate monoester hydrolysis to explore the effect of modulating leaving group pKa on the competition between solvent- and substrate-assisted pathways for the hydrolysis of these compounds. Through detailed comparative electronic-structure studies of methyl phosphate and a series of substituted aryl phosphate monoesters, we demonstrate that the preferred mechanism is dependent on the nature of the leaving group. For good leaving groups, a strong preference is observed for a more dissociative solvent-assisted pathway. However, the energy difference between the two pathways gradually reduces as the leaving group pKa increases and creates mechanistic ambiguity for reactions involving relatively poor alkoxy leaving groups. Our calculations show that the transition-state structures vary smoothly across the range of pKas studied and that the pathways remain discrete mechanistic alternatives. Therefore, while not impossible, a biological catalyst would have to surmount a significantly higher activation barrier to facilitate a substrate-assisted pathway than for the solvent-assisted pathway when phosphate is bonded to good leaving groups. For poor leaving groups, this intrinsic preference disappears.
Despite the numerous experimental and theoretical studies on phosphate monoester hydrolysis, significant questions remain concerning the mechanistic details of these biologically critical reactions. In the present work we construct a linear free energy relationship for phosphate monoester hydrolysis to explore the effect of modulating leaving group pKa on the competition between solvent- and substrate-assisted pathways for the hydrolysis of these compounds. Through detailed comparative electronic-structure studies of methyl phosphate and a series of substituted aryl phosphate monoesters, we demonstrate that the preferred mechanism is dependent on the nature of the leaving group. For good leaving groups, a strong preference is observed for a more dissociative solvent-assisted pathway. However, the energy difference between the two pathways gradually reduces as the leaving group pKa increases and creates mechanistic ambiguity for reactions involving relatively poor alkoxy leaving groups. Our calculations show that the transition-state structures vary smoothly across the range of pKas studied and that the pathways remain discrete mechanistic alternatives. Therefore, while not impossible, a biological catalyst would have to surmount a significantly higher activation barrier to facilitate a substrate-assisted pathway than for the solvent-assisted pathway when phosphate is bonded to good leaving groups. For poor leaving groups, this intrinsic preference disappears.
Phosphoryl transfer
is one of the most broadly occurring reactions
in biology, playing a central role in cellular signaling, protein
synthesis, and energy production, among other life processes.[1,2] The biological hydrolysis of phosphate esters is, in turn, facilitated
by a diverse group of enzymes, which utilize a variety of chemical
strategies to accelerate these reactions.[3−7] From a conceptual point of view, the uncatalyzed
hydrolysis of a phosphate ester should be straightforward, as it only
involves a nucleophilic displacement reaction to yield inorganic phosphate
and the corresponding alcohol. However, these esters are among the
slowest reacting biologically relevant functional groups,[8,9] making the enzymes that facilitate these reactions some of the most
proficient catalysts known to date. Following from this, despite the
considerable body of experimental and theoretical data accumulated
over the past decades (for reviews, see, e.g., refs (5 and 7) and references cited therein),
just how these reactions proceed in solution and the corresponding
enzyme-catalyzed processes remain controversial, with proposals of
multiple mechanisms for the same reaction[5,7] (Figure ) and the suggestion
that these transfer reactions may display considerable plasticity
in their character.[10]
Figure 1
Hypothetical pathways
for the hydrolysis of phosphate monoester
dianions considered in this work. (A) A concerted pathway with substrate-assisted
nucleophilic attack, in which the attacking water molecule is deprotonated
by the substrate at some point along the reaction coordinate. (B)
A stepwise pathway in which proton transfer from the nucleophile to
the substrate is concerted with nucleophilic attack, leading to a
pentacoordinate intermediate that breaks down with concerted proton
transfer to the leaving group. (C) A concerted pathway with solvent-assisted
nucleophilic attack, in which there is no proton transfer from the
nucleophile in the rate-limiting step. This figure was adapted from
ref (23).
Hypothetical pathways
for the hydrolysis of phosphate monoester
dianions considered in this work. (A) A concerted pathway with substrate-assisted
nucleophilic attack, in which the attacking water molecule is deprotonated
by the substrate at some point along the reaction coordinate. (B)
A stepwise pathway in which proton transfer from the nucleophile to
the substrate is concerted with nucleophilic attack, leading to a
pentacoordinate intermediate that breaks down with concerted proton
transfer to the leaving group. (C) A concerted pathway with solvent-assisted
nucleophilic attack, in which there is no proton transfer from the
nucleophile in the rate-limiting step. This figure was adapted from
ref (23).For example, in the case of phosphate monoester
dianions with good
leaving groups, experimental evaluation of kinetic isotope effects
(KIE),[11] linear free energy relationships
(LFER),[12,13] and entropic effects[12] have been interpreted in terms of a reaction proceeding
through a concerted pathway with a dissociative transition state (TS),
i.e., a TS that has little bonding to the nucleophile and leaving
group, in contrast to the more associative TSs expected for the hydrolysis
of phosphate di- and triesters (see discussion in, e.g., ref (5)). On the other hand, computational
studies have suggested two viable concerted pathways with TS that
are either dissociative or associative in nature, depending on the
pKa of the leaving group.[14−17] These pathways can be viewed as extremes on a relatively flat potential
surface, where the TS structure changes extensively as the nature
of the leaving group is changed, or competing processes, where the
TS structures for each pathway are similar regardless of the leaving
group (and there is a large energetic penalty if the structure is
distorted).[18,19] Finally, it has been suggested
that the qualitative interpretation of traditional experimental markers
such as LFER,[15,20,21] activation entropies,[17] and KIE[15] can be ambiguous, with different pathways potentially
giving rise to similar experimental observables.[20]Of the range of experimental approaches that can
be used to distinguish
different pathways, LFER have proven to be particularly useful for
probing the bonding patterns and charge distributions of the TSs across
a series of homologous substituted compounds.[22] Specifically, by examining the effect of adding electron-donating
or -withdrawing groups to the leaving group of a reactant on the corresponding
reaction rate, LFER measure the sensitivity of the reaction to charge
changes at the position of bond cleavage during the reaction. The
steeper the correlation between the rate constant and the pKa of the leaving group (or, more formally, the
equilibrium constant of the reaction for a fundamental step), the
more advanced bond cleavage is likely to be at the TS, provided that
the variations in structure are sufficiently far from the reaction
center to avoid changes caused by steric effects and that the total
electronic changes are not so large as to cause a large variation
in TS structure.[24]There exist several
LFER for phosphoryl and related group transfer
reactions in the literature;[5] however,
most of the experimental data used to analyze LFER for phosphoryl
transfer reactions have been obtained using good leaving groups. For
example, Kirby et al.[13] examined the LFER
for the cleavage of both phosphate ester mono- and dianions at 39
°C. In doing so, they obtained a steep leaving group dependence
with a Brønsted coefficient (βlg) of −1.23
for phosphate monoester dianions using leaving groups with pKas <7.2 (βlg = −1.26
if the value for phenol from Lad et al.[8] is also included) and very little leaving group dependence (βlg = −0.27) for phosphate monoester monoanions (the
insensitivity to the leaving group allowed these data to include substrates
with relatively poor leaving groups, such as methyl phosphate). They
also observed a small (but systematic) deviation from the original
straight line for ortho-substituents, with o-nitro
groups being hydrolyzed more quickly and o-chloro
substituents being hydrolyzed more slowly than would have been expected
from the original relationship. The high sensitivity of the rate of
hydrolysis of the dianions to leaving group pKa was interpreted as resulting from a loose TS with extensive
bond cleavage to the leaving group, which is corroborated by the KIE
studies of Hengge and co-workers.[11]As ref (13) considered
only good leaving groups, Lad and co-workers[8] later extended the range of compounds studied to also include phenyl
phosphate (pKa = 10) and alkoxy phosphates
as leaving groups. The corresponding thermodynamic parameters for
phenyl phosphate, i.e., an enthalpy of activation of 38 ± 2 kcal·mol–1 and slightly positive activation entropy of 7 ±
2 cal·mol–1·K–1, were
interpreted as evidence that the reaction proceeds via a loose TS
as proposed for other aryl phosphate dianions (although the complications
with inferring mechanism from activation entropies have been discussed
below). Using an Arrhenius plot to extrapolate the observed rate constants
to 39 °C gives an estimated rate constant of 1 × 10–12 s–1, which is in good agreement
with the LFER prediction of the previous data (Figure ). Similarly, measuring the hydrolysis of
methyl and neopentyl phosphate at high temperature led to an estimated
rate constant for the hydrolysis of alkoxy phosphate dianions of 2
× 10–17 s–1 at 39 °C.[8] Unlike the other data, this datum involves the
specific acid-catalyzed reaction of the phosphate dianion and so represents
an upper limit for the spontaneous reaction (see discussion below).
The LFER predicts a value of 5 × 10–19 s–1 at 39 °C for methoxide as a leaving group, which
is consistent with this observation and provides the current experimental
estimate for the reactivity of a phosphate dianion with an alkoxy
leaving group.
Figure 2
Observed βlg for the spontaneous hydrolysis
of
phosphate dianions: benzoyl phosphates (gray, data from ref (25)); monoaryl phosphates
with no ortho substituents (black); monoaryl phosphates
with 2-nitro groups (red); monoaryl phosphates with 2-chloro groups
(blue). Data from ref (13) at 39 °C except for phenyl phosphate, where the value was extrapolated
from measurements at higher temperature, as reported in ref (8)). The green circle is for
methyl phosphate in 1 M KOH, where the value was extrapolated from
measurements at higher temperature as reported in ref (8). The data used to create
this figure are given in Table S1.
Observed βlg for the spontaneous hydrolysis
of
phosphate dianions: benzoyl phosphates (gray, data from ref (25)); monoaryl phosphates
with no ortho substituents (black); monoaryl phosphates
with 2-nitro groups (red); monoaryl phosphates with 2-chloro groups
(blue). Data from ref (13) at 39 °C except for phenyl phosphate, where the value was extrapolated
from measurements at higher temperature, as reported in ref (8)). The green circle is for
methyl phosphate in 1 M KOH, where the value was extrapolated from
measurements at higher temperature as reported in ref (8). The data used to create
this figure are given in Table S1.We have recently performed a detailed
study of the mechanisms of
phosphate monoester hydrolysis in aqueous solution, considering the
competition between a solvent-assisted pathway with a loose TS and
a substrate-assisted reaction pathway with a more compact TS, comparing
their energetics and using calculated KIEs as a tool to discriminate
between different pathways.[23] Experimental
evidence that we did not consider in detail in this work was the leaving
group dependence of the hydrolysis of these compounds, as we only
considered the two extremes of a very good and a very poor leaving
group. It has been suggested, from extensive density functional theory
(DFT) calculations of the energy landscapes for the hydrolysis of
a range of phosphate monoester dianions, that the choice of reaction
mechanism is dependent on the pKa of the
leaving group,[15,16] whereby the better the leaving
group, the more dissociative the TS. However, a limitation of the
study in ref (15) is
that it only considered the pathways directly observed on the calculated
3D energy landscapes (defined in terms of bond making and bond breaking
coordinates and the associated energy changes). While this provides
some insight into potential choices of mechanism, examining only the
calculated 3D energy landscapes can miss the preferred reaction pathways[23,26,27] when more complex reaction coordinates
are involved, e.g., with multiple bonds being formed and broken simultaneously.The purpose of this work is to complete the mechanistic picture
for aryl phosphate monoester hydrolysis by examining this central
piece of experimental evidence, namely, the LFER for the hydrolysis
of these compounds, to explore how the leaving group affects both
the solvent- and substrate-assisted pathways for the hydrolysis of
phosphate monoester dianions. This, in turn, leads to greater insights
into the likely competition between these processes for compounds
with different structures. We have analyzed the energetics for each
of the two pathways by DFT calculations using the M06-2X[28] and ωB97X-D[29] functionals. Our results show that while there is a clear preference
for a dissociative, solvent-assisted pathway for the hydrolysis of
compounds with good leaving groups, this gradually diminishes such
that a crossover to a more associative, substrate-assisted pathway
becomes increasingly plausible with poorer leaving groups. We discuss
the implications of this observation for understanding the mechanisms
of enzyme-catalyzed phosphoryl transfer reactions.
Materials and Methods
The different reaction pathways
analyzed in this study are schematically
presented in Figure . In our recent work[23] we obtained TSs
for 4-nitrophenyl hydrolysis through both solvent- and substrate-assisted
pathways, in the presence of eight water molecules, optimized at the
M06-2X/6-31+G(d) level of theory. These structures were used as starting
points to obtain TSs for the hydrolysis of all other compounds shown
in Figure , by perturbing
the initial TS through replacement of the substituent and reoptimizing
the resulting structures using the 6-31+G(d) basis set with either
the M06-2X[28] (Tables S2–S3) or the ωB97X-D functionals[29] (Tables S4–S5). Both
are dispersion corrected functionals and have been successfully applied
to the study of a wide range of mechanistic questions.[30−32]
Figure 3
Aryl
phosphate monoester dianions examined in this work. These
were selected to give a wide range of pKa values, ensuring hydrogen is in the ortho positions
to avoid direct interactions between the reaction center and the substituents.
Aryl
phosphate monoester dianions examined in this work. These
were selected to give a wide range of pKa values, ensuring hydrogen is in the ortho positions
to avoid direct interactions between the reaction center and the substituents.Solvation was accounted for by
using a mixed explicit/implicit
solvent model, comprising of eight explicit water molecules (not including
the nucleophilic water molecule) and the solvent model density (SMD)
implicit model,[33] as in our recent work.[23] We note that when using only a limited number
of explicit water molecules, the calculated energetics are strongly
dependent on the precise positioning of the water molecules, as different
stabilizing interactions will be created based on where they are placed.
However, we demonstrated in ref (23) that once a sufficient number of explicit water
molecules are added, this problem is mitigated as potential interaction
partners become saturated with explicit hydrogen-bonding interactions,
and the calculations become less sensitive to the precise number of
water molecules included in the model. We found that for simple phosphate
monoester dianions, eight explicit water molecules provided a good
compromise between the computational cost and reliability of the calculations.
In particular, the results we obtained for methyl phosphate hydrolysis
with eight water molecules included in the calculation (in addition
to the nucleophile) where very similar to those obtained by Schlitter[34] using full explicit solvation, increasing our
confidence in the reliability of the model. Water molecules were added
to the system symmetrically (alternately adding one to the leaving
group or the nucleophile side of the central PO3 group
at the TS) to avoid overstabilizing one side of the reacting system
compared to the other.Finally, the resulting TS were characterized
by frequency calculations,
as well as by following the intrinsic reaction coordinate (IRC)[35,36] to minima in both directions, followed by unconstrained geometry
optimizations at the same level of theory. In all cases, the optimization
was performed using an ultrafine numerical integration grid and tight
optimization criteria (as implemented in Gaussian 09),[37] with the exception of a few stationary points,
mainly in the product states, where it was impossible to obtain a
convergent structure with tight optimization criteria. Additional
single point frequency calculations were performed on the key stationary
points using the larger 6-311+G(d,p) basis set and a scaling factor
of 0.970 by analogy to related basis sets,[38] in order to correct for zero-point energies and entropies and obtain
the final free energies for these reactions. Finally, in all cases
we compared the energetics of the final optimized reactant states
obtained from following the IRC for each pathway, and the lowest energy
of these was used as a reference state for both pathways as this is
closer to the global minimum on the energy surface and allows us to
compare both TSs relative to the same reference state (see ref (23)). All electronic-structure
calculations presented in this work have been performed using the
Gaussian 09 simulation package (revision D.01).[37]
Results and Discussion
Leaving Group Effects and the Competition
Between Substrate-
and Solvent-Assisted Mechanisms
Figure provides an overview of the different possible
mechanisms for phosphate monoester hydrolysis, which could be very
close in energy, as suggested in refs (14, 15, 17, 23, and 34). To assess how
changing the leaving group affects the competition between substrate-
and solvent-assisted pathways, we examined the hydrolysis of a series
of aryl phosphate monoesters with eight different leaving groups (Figure ), spanning a pKa range from 6.7 to 10, as well as the hydrolysis
of methyl phosphate. In each case, two potential pathways were studied:
a substrate-assisted mechanism, in which nucleophilic attack occurs
in either a concerted or stepwise fashion and is coupled with proton
transfer from the attacking water molecule to one of the nonbridging
oxygens of the phosphate, and a solvent-assisted mechanism, in which
the nucleophile is not deprotonated in the rate-limiting TS but is
stabilized by the solvent (see also Figure for details).A comparison of the
calculated energetics of the two different pathways obtained at the
SMD-M06-2X/6-311+G(d,p)//SMD-M06-2X/6-31+G(d) and SMD-ωB97X-D/6-311+G(d,p)//SMD-ωB97X-D/6-31+G(d)
levels of theory are illustrated in Figure , with the corresponding data shown in Table . All calculations
were performed with eight explicit water molecules in order to solvate
the reacting fragments appropriately, as discussed in our previous
work.[23] Additionally, our reference state
for both mechanisms is the reactant complex with the lowest absolute
energy obtained from following the IRC on the two different pathways,
to allow for direct comparison between the two pathways from the same
reference state. The absolute energetics of each species is also provided
as Supporting Information for comparison.
Figure 4
Calculated activation
energies for the addition of water to the
aryl phosphate dianions shown in Figure as well as to the methyl phosphate dianion
via either a solvent (blue solid circles) or substrate-assisted (black
solid circles) pathway. The energies were obtained at the (left) SMD-M06-2X/6-311+G(d,p)//SMD-M06-2X/6-31+G(d)
and (right) SMD-ωB97X-D/6-311+G(d,p)//SMD-ωB97X-D/6-31+G(d)
levels of theory, respectively, with the corresponding numerical values
presented in Table .
Table 1
Energetics for the Spontaneous Hydrolysis
of the Aryl Phosphate Monoesters Shown in Figure , through Either Substrate- Or Solvent-Assisted
Pathwaysa
systems
substrate-assisted
pathway
solvent-assisted
pathway
M06-2X
ωB97X-D
M06-2X
ωB97X-D
pKa
ΔGstep1⧧
ΔGstep2⧧
ΔGstep1⧧
ΔGstep2⧧
ΔG⧧
ΔG⧧
3,5-NO2
6.68
28.3
–
31.5
–
25.9
25.2
4-NO2
7.14
28.8
–
31.7
–
27.1
24.8
3-NO2, 4-Cl
7.78
29.4
25.7
32.3
–
28.7
27.9
3-NO2
8.35
29.6
26.7
34.2
–
29.8
29.2
3,4-Cl
8.63
29.4
26.1
32.6
–
30.6
28.7
3-Cl
9.02
30.0
27.6
34.2
31.1
31.1
31.2
4-Cl
9.38
30.7
29.0
34.9
30.8
32.5
31.3
H
10.0
30.6
29.4
33.7
30.7
33.0
32.5
methyl
15.5
33.1
35.6
35.3
40.1
44.1
43.8
In the case of the substrate-assisted
pathway, ΔGstep1⧧ and ΔGstep2⧧ correspond to the activation free energies of the addition and elimination
steps, respectively. In cases where the energy of the elimination
step is represented as “–”, the reaction proceeds
through a concerted pathway with a single TS. In the case of the solvent-assisted
pathway, the reaction also proceeds through a single TS throughout,
the activation free energy of which is represented by ΔG⧧. Frequency calculations were performed
at 312 K. A more detailed energy decomposition for each pathway is
presented in Tables S2–S5. All energies
are presented in kcal·mol–1 at the SMD-M06-2X/6-311+G(d,p)//SMD-M06-2X/6-31+G(d)
and SMD-ωB97X-D/6-311+G(d,p)//SMD-ωB97X-D/6-31+G(d) level
of theory relative to the lowest-energy reactant state for the two
pathways.
In the case of the substrate-assisted
pathway, ΔGstep1⧧ and ΔGstep2⧧ correspond to the activation free energies of the addition and elimination
steps, respectively. In cases where the energy of the elimination
step is represented as “–”, the reaction proceeds
through a concerted pathway with a single TS. In the case of the solvent-assisted
pathway, the reaction also proceeds through a single TS throughout,
the activation free energy of which is represented by ΔG⧧. Frequency calculations were performed
at 312 K. A more detailed energy decomposition for each pathway is
presented in Tables S2–S5. All energies
are presented in kcal·mol–1 at the SMD-M06-2X/6-311+G(d,p)//SMD-M06-2X/6-31+G(d)
and SMD-ωB97X-D/6-311+G(d,p)//SMD-ωB97X-D/6-31+G(d) level
of theory relative to the lowest-energy reactant state for the two
pathways.Calculated activation
energies for the addition of water to the
aryl phosphate dianions shown in Figure as well as to the methyl phosphate dianion
via either a solvent (blue solid circles) or substrate-assisted (black
solid circles) pathway. The energies were obtained at the (left) SMD-M06-2X/6-311+G(d,p)//SMD-M06-2X/6-31+G(d)
and (right) SMD-ωB97X-D/6-311+G(d,p)//SMD-ωB97X-D/6-31+G(d)
levels of theory, respectively, with the corresponding numerical values
presented in Table .The trends in these data show
that the mechanistic preference between
the two pathways changes across the series, with the solvent-assisted
pathway being preferred for the best leaving groups and the substrate-assisted
pathway being preferred for poor leaving groups. For both functionals,
the calculated change in energy across the series for the solvent-assisted
pathway is substantial, with the energetics increasing by about 7
kcal·mol–1 upon moving from the best to the
poorest leaving group in the series of aryl phosphates. In contrast,
the calculated energetics of the substrate-assisted pathway are more
constant and do not change by more than 2 kcal·mol–1 across the series. Both functionals give a similar set of absolute
values for the solvent-assisted pathway, but give significantly different
values for the substrate-assisted pathway (by almost 6 kcal mol–1). This leads to quite different predictions for where
the crossover between the two pathways will occur. For the M06-2X
functional, this occurs at pKa of 8.4
(i.e., at the 3-nitrophenyl leaving group), but for the ωB97X-D
functional one would expect a crossover between the two pathways at
a pKa ∼ 11. Overall, both sets
of calculations provide a consistent picture of the trends in reactivity
with changing leaving group for both pathways, but provide different
predictions of their relative importance.These data can also
be expressed as Brønsted plots for the
hydrolyses of these compounds to allow comparison with the experimental
data (Figure ). In
the case of the solvent-assisted pathway, a steep linear correlation
is obtained with βlg values of −1.42 ±
0.03 (M06-2X) and −1.51 ± 0.07 (ωB97X-D), as would
be expected from a TS with extensive cleavage to the leaving group
and is in good agreement with that obtained experimentally (βlg value of −1.26 ± 0.07).[8,39] For
the substrate-assisted pathway, an intermediate forms for compounds
with pKa <7.5 (M06-2X) or 9.0 (ωB97X-D);
for compounds with lower pKas, the intermediate
becomes a shoulder on the potential energy curve, and the reaction
is concerted but dominated by bond formation to the nucleophile, i.e.,
the TS is similar to the formation of the intermediate when the reaction
is stepwise. The steepness of the correlation depends on which step
is rate limiting. When this is bond formation, βlg values of −0.37 (M06-2X) and −0.28 (ωB97X-D)
are obtained; when the second step is rate limiting, βlg values of −0.89 (M06-2X) and −1.05 (ωB97X-D)
are obtained. These are combined in Figure to show the predicted values of the observed
rate constant for each compound. The point at which the rate-limiting
step changes differs slightly depending on functional (12.1 for M06-2X
and 11.8 for ωB97X-D, respectively), which is well before the
nucleophile and leaving group have similar leaving group abilities.
This may be due to the fact that the proton that is transferred from
the nucleophilic water to the nonbridging oxygen is still in position
to make the nucleophile behave as a much better leaving group through
intramolecular general acid catalysis. For example, our data (Tables S2–S5) show that the status of
any intermediates appears to be marginal, with even rotation of the
P–OH group being potentially too slow to intervene in the reaction.
It has been argued that a substrate-assisted pathway involving an
additional water molecule that acts as a bridge between the nucleophile
and the nonbridging oxygens of the phosphate has a lower energy than
direct proton transfer from the nucleophile.[40,41] However, in our previous work, the presence of intervening water
molecules to facilitate proton transfer did not enhance proton transfer
between bridging and nonbridging positions.[23] In addition, the nonlinear Brønsted plot may have similarities
to the behavior of RNA models under basic conditions, which are also
nonlinear, but where the dianionic intermediate is believed to have
marginal stability and only partitions between substrate and product.
In that case, the break in the plot is much closer to the pKa of the incoming nucleophile, but no proton
transfers are involved.[42]
Figure 5
Brønsted plots for
the spontaneous hydrolysis of the aryl
phosphate monoesters shown in Figure and for methyl phosphate. For the substrate-assisted
pathway, steps 1 (black) and 2 (blue) are plotted individually (dotted
lines), and combined to show the predicted overall rate constant (solid
black line). The solvent-assisted pathway is shown with a linear least-square
fit (red). Energy calculations were performed at 312 K at the SMD-M06-2X/6-311+G(d,p)//SMD-M06-2X/6-31+G(d)
and SMD-ωB97X-D/6-311+G(d,p)//SMD-ωB97X-D/6-31+G(d) levels
of theory. Rate constants were obtained from the calculated activation
free energies, using TS theory.
Brønsted plots for
the spontaneous hydrolysis of the aryl
phosphate monoesters shown in Figure and for methyl phosphate. For the substrate-assisted
pathway, steps 1 (black) and 2 (blue) are plotted individually (dotted
lines), and combined to show the predicted overall rate constant (solid
black line). The solvent-assisted pathway is shown with a linear least-square
fit (red). Energy calculations were performed at 312 K at the SMD-M06-2X/6-311+G(d,p)//SMD-M06-2X/6-31+G(d)
and SMD-ωB97X-D/6-311+G(d,p)//SMD-ωB97X-D/6-31+G(d) levels
of theory. Rate constants were obtained from the calculated activation
free energies, using TS theory.The similarities in both the trends and the energetics for
the
solvent-assisted pathway obtained using two different functionals
and the good agreement with the experimental data suggest that this
is a sufficient explanation of the observed data for the spontaneous
hydrolysis of aryl phosphate dianions, although it does not preclude
a contribution or near contribution from the substrate-assisted pathway.
Our previous work strongly suggests that the 4-nitrophenyl phosphate
dianion reacts primarily through the solvent-assisted pathway due
to the KIE that has been measured and calculated for this compound.
The substrate-assisted pathway also shows a consistent trend for both
functionals, but there is a much weaker dependence of the activation
energy on the pKa of the aryloxide leaving
group when the reaction is dominated by nucleophilic attack (and a
weaker dependence when leaving group departure is rate limiting).
As the correlations between the energy and pKa for the two pathways are significantly different, this leads
to the conclusion that there will be some leaving groups where the
two pathways have a similar energy barrier, and, after this point,
there will be a change in the dominant mechanistic pathway for the
reaction from solvent- to substrate-assisted. However, the absolute
activation energies of the substrate-assisted pathway do appear to
be sensitive to the functional, and this means that the predicted
crossover point differs for the two sets of calculations. To try and
refine where the crossover may occur, we also consider the kinetic
and thermodynamic experimental data that exists.Thermodynamically,
Guthrie has measured parameters for a series
of phosphorane species, leading to estimates of the likely relative
stabilities of the key intermediates for the two pathways.[43] For a fully dissociative pathway involving the
formation of metaphosphate, the free energy of the equilibrium, where
an ethoxy anion is fully dissociated from the dianion of ethyl phosphate,
is 37 ± 3 kcal·mol–1. This figure was
derived from kinetic data for phosphate monoesters with good leaving
groups by assuming the formation of metaphosphate followed by rate-limiting
attack of water, which was estimated to have a rate constant of 10–9 s–1. This corresponds to an additional
barrier of ∼5.4 kcal·mol–1, leading
to an overall barrier ∼42 kcal·mol–1 for forming the initial product on the solvent-assisted pathway,
which is in very good agreement with our calculated values for the
solvent-assisted pathway. We note that our calculations do not predict
the formation of a formal metaphosphate intermediate, in keeping with
the conclusions from additional experiments involving stereochemical
probes;[44−46] the difference in the two analyses is whether there
is any bonding to the leaving group in the TS (see below). Guthrie
also combined thermochemical data for ethoxy phosphoranes with estimated
pKas to calculate the enthalpy of addition
of water to ethyl phosphate dianion,[43] and
the value is 33 ± 4 kcal·mol–1, which
is in very good agreement with the calculated energy for the formation
of the intermediate formed in the substrate-assisted pathway. Thus,
for the methoxy leaving group, the thermodynamics suggest that both
pathways involve species that have comparable stabilities. For these
poor leaving groups, the difference between the two pathways depends
on the intrinsic barrier for the reactions, which has been assumed
to be more substantial for phosphorane formation due to the movement
of more heavy atoms. Our calculations suggest that there is not a
large intrinsic barrier to the decomposition of the marginally stable
dianionic phosphorane, which is why this pathway appears to be competitive
with the solvent-assisted pathway for these leaving groups. This may
be because the initially formed intermediate has a phosphoryl proton
(received from the nucleophile) poised to allow intramolecular general
acid catalysis of the departure of the leaving group in a process
similar to that suggested for the reactions of phosphate monoester
monoanions.As noted above, the dianion of phenyl phosphate
appears to have
a rate constant that is consistent with the experimental LFER obtained
for lower pKa leaving groups and to be
accounted for by the solvent-assisted pathway. Thus, the substrate-assisted
pathway does not appear to be dominant for this compound, although
it could be similar energetically. The data for phosphate monoester
dianions with much poorer leaving groups (methanol or neopentyl alcohol)
are even sparser. The data revealed this even in 1 M KOH, the dominant
reaction involves specific acid catalysis, which is kinetically equivalent
to the reaction of the very small amount of monoester monoanion present.
Extrapolating these data to 100 °C agrees very well with predictions
from the pH rate profile for methyl phosphate at this temperature
(Figure A). In this
figure, the circle is the datum extrapolated from high temperature
in 1 M KOH. The limiting values at high pH (dotted lines) are the
estimates of the dianion reaction from the LFER, assuming a similar
entropy of activation to the phenyl phosphate dianion. These data
show that the spontaneous reaction is even slower over the range these
data were measured. Similarly, extrapolating the data for the reaction
of the monoanion to 39 °C and combining this with the second
pKa for methyl phosphate also agree with
predicted rate constant derived from the data measured in 1 M KOH
at high temperature.
Figure 6
(A) pH dependence of methyl phosphate hydrolysis. The
black line
(39 °C) was obtained by using the data reported for the hydrolysis
of the monoanion at 100 °C and the reported activation parameters
and a value of 6.3 for the second pKa of
methyl phosphate. The blue line was obtained from the data reported
for the hydrolysis of the monoanion at 100 °C, and the circle
is the datum extrapolated from high temperature in 1 M KOH. (B) Temperature
dependence of methyl phosphate hydrolysis. The black circles and line
are the experimental data reported for methyl phosphate in 1 M KOH.
The red point is the predicted rate constant for the solvent-assisted
mechanism according to the Brønsted plot at 39 °C. The blue
dashed lines illustrate the predictions for a potential substrate-assisted
mechanisms with the entropy of activation fixed at −12 eu.
For the corresponding temperature dependence, see Figure S1.
(A) pH dependence of methyl phosphate hydrolysis. The
black line
(39 °C) was obtained by using the data reported for the hydrolysis
of the monoanion at 100 °C and the reported activation parameters
and a value of 6.3 for the second pKa of
methyl phosphate. The blue line was obtained from the data reported
for the hydrolysis of the monoanion at 100 °C, and the circle
is the datum extrapolated from high temperature in 1 M KOH. (B) Temperature
dependence of methyl phosphate hydrolysis. The black circles and line
are the experimental data reported for methyl phosphate in 1 M KOH.
The red point is the predicted rate constant for the solvent-assisted
mechanism according to the Brønsted plot at 39 °C. The blue
dashed lines illustrate the predictions for a potential substrate-assisted
mechanisms with the entropy of activation fixed at −12 eu.
For the corresponding temperature dependence, see Figure S1.Adding the rate constant
for the spontaneous reaction of the dianion
predicted by the Brønsted plot at 39 °C shows that this
reaction is expected to be about 300-fold lower than that derived
from the Arrhenius plot of the reaction in 1 M KOH. This means that
a mechanistic change is only expected when the pH is >16 and indicates
that the spontaneous reaction of the dianion is invisible over the
usual pH range at this temperature. The observed value for the enthalpy
of activation for this reaction (44.7 kcal·mol–1) is very similar to the value we have calculated for the solvent-assisted
reaction 44 kcal·mol–1), slightly higher than
derived from Guthrie’s data[43] (above;
42 kcal·mol–1) and slightly lower than the
value obtained (46 kcal·mol–1) by combining
the value from the Brønsted plot at 39 °C with the measured
entropy of activation for phenyl phosphate.[8] Using any of these estimates that the difference between the two
pathways will remain about 2 orders of magnitude at any temperature
where experiments can be carried out and the direct observation of
the solvent-assisted pathway is not possible.The experimental
data from high temperature measurements and the
Brønsted plot have been the basis of the best estimate for the
spontaneous hydrolysis of the methyl phosphate dianion and provide
a lower limit for the reactivity for the spontaneous hydrolysis of
the methyl phosphate dianion. However, as shown in Figure B, it is possible that a slower
reaction at higher temperature with a lower enthalpy of activation
could become the dominant reaction at ambient temperature. Such a
reaction would be invisible to extrapolations from the Arrhenius (as
the reaction of a different ionic species is dominant) and Brønsted
analyses (which predicts the rate constant for the solvent-assisted
pathway). Thus, the experimental data available do not rule out a
transition to a substrate-assisted pathway for leaving groups with
higher pKa than phenol. Figure B illustrates some limiting
cases for methyl phosphate hydrolysis, assuming that a 10% or lower
contribution to the observed rate constant for the last experimental
data point would not be detectable in an Arrhenus plot (i.e., no detectable
deviation from linearity in the data; it is likely that a greater
contribution would also be undetectable). In this figure, the upper
line is for a reaction that contributes 10% of the observed rate constant
for the experimental data point at the lowest temperature and has
an enthalpy of activation of 36.5 kcal·mol−1, which predicts a rate constant of 4 × 10−16 s−1 at 39 °C (∼1000 fold greater than
predicted by the Brønsted plot). The lower line is for a reaction
with the same rate constant at 39 °C as the solvent-assisted
reaction predicted by the Brønsted plot, but an enthalpy of activation
of 40.7 kcal·mol−1. This lower line would contribute
<0.1% of the experimentally observed rate constant at the lowest
temperature.These limiting cases show that an alternative reaction pathway
with an enthalpy of activation between 36.5 and 40.7 kcal·mol–1 has a rate constant at least as large as that predicted
by the Brønsted plot at 39 °C, but is experimentally invisible
under any accessible conditions or practical timescales. These estimates
are based on an entropy of activation of −12 eu, as a plausible
value for the addition of solvent to the phosphate dianion. We note
that intepreting and predicting the entropy of activation is difficult,
as this measurement includes changes in both the reacting system the
solvent environment, and so this value is merely a conventional approximation
for a reaction between a substrate and the solvent. If the entropy
of activation is closer to zero, then the enthalpy of activation would
need to be closer to the experimental value for an alternative reaction
to be both dominant at lower temperature and undetectable at higher
temperature. We also note that the experimental data for methyl phosphate
at high pH indicate that it is an acid catalyzed reaction between
the dianion and acid and has an observed entropy of activation of
+6 eu and that 4-nitrophenyl sulfate undergoes a solvent-assisted,
dissociative reaction with solvent, and has an entropy of activation
of −18.5 eu. Thus,
this parameter should be considered with caution and preferably in
conjunction with other observables for diagnosing mechanisms.Interestingly, the intermediate formed is similar to that obtained
from hydroxide addition to a phosphate diester (where the equatorial
proton is replaced by an alkyl group, see Figure S2 for the Brønsted plot of the second-order rate constant
for hydroxide-promoted hydrolysis of phosphate diesters). The comparison
between spontaneous reaction of a dianion and hydroxide attack at
the monoanion presents some difficulties as it involves the use of
model reactions and the attendant assumptions to be made.[47,48] Using dimethyl phosphate as a model compound for the reaction of
hydroxide with methylphosphate monoanion and calculating the fraction
of methyl phosphate in the correct ionic form to react by, this mechanism
reaction predicts that the overall reaction (∼3 × 10–20 s–1) is slightly slower than for
the solvent-assisted pathway predicted by the LFER extrapolation (∼5
× 10–19 s–1). This assumes
that the ionic form as a pair of stable species is on the reaction
pathway and that their reaction is similar to the equivalent reaction
of a diester. If proton transfer only occurs within the reactant complex
(i.e., general base catalysis by the substrate of addition by water),
then this assumption is not necessarily applicable and the barrier
for the addition may be lower that that obtained from this extrapolation.The relative merits of the two pathways have also been considered
by Vigroux et al.,[16] who studied the substrate-assisted
pathway for a series of aryl and alkyl phosphate monoester dianions
using computational methods and compared them with the experimental
LFER. The authors concluded that while this pathway was unlikely to
apply to aryl phosphates, it was feasible for the hydrolysis of alkyl
phosphate esters. They predicted a crossover at pKa = 13 based on comparison between their calculated alkyl
compounds and the available experimental data for aryl compounds,
which was assumed to proceed by a dissociative pathway (but was not
explicitly modeled). The substrate-assisted mechanism proceeded through
concerted pathways and was sensitive to the positioning of the proton
on the monoester. In this and previous work, these authors suggested
that although an alkyl group was a reasonable substitute for a proton
on the nonbridging phosphoryl oxygen, the protonated species was slightly
more reactive.Overall, based on this analysis, the available
experimental data
suggest that mechanistic ambiguity is plausible for phosphate monoester
dianions with poor leaving groups, although the energetic preference
for the solvent-assisted pathway is likely to be strongly preferred
for substrates with very good leaving groups.
Corresponding Transition-State
Geometries
As a final
note, Figures and S3 show comparison of changes in P–O bond
orders and geometries at the TS to the incoming nucleophile (P–Onuc) and departing leaving group (P–Olg)
upon changing the pKa of the leaving group.
From these figures, it can be seen that changing the nature of the
leaving group has little effect on the TS structure for either pathway
across the series (apart from becoming slightly tighter with poorer
leaving groups) and with either functional. Using M06-2X, the substrate-assisted
process becomes stepwise at a pKa of 7.78,
but with ωB97X-D, an intermediate only forms when the leaving
group pKa is 9.02. In both cases, nucleophilic
attack remains rate-limiting as the barrier to subsequent elimination
of the leaving group is very low. In contrast, for the solvent-assisted
pathway, the process is always concerted. As can be seen from Figure , upon moving from
good to poor leaving groups, there is a small increase in the P–Onuc bond order and a very small decrease in the P–Olg bond order at the TS, such that the overall bonding in the
TS does not change much across the series. Therefore, despite the
uncertainities about the crossover point between the substrate- and
solvent-assisted pathways, the energetic trends presented in Figure are in good qualitative
agreement with the rate-limiting TS structures obtained for each pathway:
the solvent-assisted mechanism involves greater bond cleavage to the
leaving group than the substrate-assisted mechanism, and so a corresponding
greater sensitivity to the leaving group is observed.
Figure 7
Calculated Wiberg bond
indexes to the incoming nucleophile (P–Onuc, solid
squares) and departing leaving group (P–Olg, solid
circles) at the TS of the rate-limiting step for
the (A) substrate- and (B) solvent-assisted hydrolysis of the compounds
shown in Figure at
the SMD-M06-2X/6-311+G(d,p)//SMD-M06-2X/6-31+G(d) (black) and SMD-ωB97X-D/6-311+G(d,p)//SMD-ωB97X-D/6-31+G(d)
(blue) levels of theory. For the corresponding numerical values see Table S6. The corresponding distances are presented
in Figure S4 and Table S7.
Calculated Wiberg bond
indexes to the incoming nucleophile (P–Onuc, solid
squares) and departing leaving group (P–Olg, solid
circles) at the TS of the rate-limiting step for
the (A) substrate- and (B) solvent-assisted hydrolysis of the compounds
shown in Figure at
the SMD-M06-2X/6-311+G(d,p)//SMD-M06-2X/6-31+G(d) (black) and SMD-ωB97X-D/6-311+G(d,p)//SMD-ωB97X-D/6-31+G(d)
(blue) levels of theory. For the corresponding numerical values see Table S6. The corresponding distances are presented
in Figure S4 and Table S7.
Overview and Conclusions
In this
study, we have explored leaving group effects on the competition
between solvent- and substrate-assisted mechanisms for phosphate monoester
dianion hydrolysis. As well as being a valuable mechanistic probe,
these effects are important to understand, given the wide variety
of leaving groups that are found in natural phosphates. We demonstrate
that the mechanistic choice between the two pathways is dependent
on the nature of the leaving group, with good leaving groups preferring
a more dissociative solvent-assisted TS. However, moving to poorer
leaving groups gradually reduces the energy difference between the
two pathways and will ultimately lead to a preference for the substrate-assisted
pathway, with the crossover point likely to occur for simple alcohol
leaving groups.There have been extensive computational studies
of the uncatalyzed
hydrolysis of phosphate monoesters with poor leaving groups,[14,16,34] but very few of the corresponding
uncatalyzed hydrolysis of phosphate monoesters with good leaving groups.[23,49] In accurately reproducing the LFER for phosphate monoester hydrolysis,
we demonstrate how the competition between the possible pathways varies
with the leaving group. A detailed analysis of the available experimental
data suggests that the competition between the two pathways is plausible
for simple alcohols but also demonstrates that direct kinetic characterization
of these reactions is not accessible due to competing processes and
experimental limitations on measuring extremely slow reactions.The possibility of such competition between two pathways has implications
for our understanding of enzyme-catalyzed phosphoryl transfer reactions,
that is, while the relevant enzymes would have to overcome a larger
energy barrier to facilitate the hydrolysis of a phosphate monoester
with a good leaving group (such as for instance GTP or ATP) through
a substrate-assisted pathway, such a pathway would be viable for enzymes
that catalyze the hydrolysis of phosphate esters with poor leaving
groups (such as serine/threonine or possibly even tyrosine phosphatases),
and such a mechanistic possibility needs to be seriously considered.
Irrespective of the preferred pathway in aqueous solution, it is of
course feasible that this preference could be changed in the nonhomogenous
environment of an enzyme active site or a synthetic catalyst, provided
that the intrinsic energy difference between the two pathways is sufficiently
small.Furthermore, we note that if an enzyme has evolved to
catalyze
phosphate hydrolysis with a poor leaving group, this could reasonably
occur through either pathway, presumably with different local interactions.
When presented with a substrate with a better leaving groups, both
sets of interactions would lead to faster turnover of this substrate,
although the associative pathway would reduce the rate less if the
same amount of TS stabilization is achieved. In contrast, if an enzyme
has evolved to stabilize the dissociative reaction of a monoester
with a good leaving group, the transition to a poor leaving group
would have a higher penalty. Finally, if an enzyme has evolved to
stabilize the more compact dianionic TSs apparently favored in the
alkaline hydrolysis of phosphate diesters,[5,7] it
may be feasible to transfer sufficient activity toward phosphate monoester
dianion hydrolysis through a substrate-assisted pathway to provide
an evolutionary beneficial function. This is reflected by/in line
with the high promiscuous phosphomonoesterase activities observed
in a number of promiscuous phosphodiesterases,[50−52] suggesting
that these enzymes can hydrolyze phosphate monoester hydrolysis through
compact substrate-assisted TSs that are similar in geometry and charge
distribution to those of the reactions of their diester counterparts.
In contrast, an active site that has evolved to accommodate a loose
solvent-assisted pathway for phosphate monoester hydrolysis is not
well equipped to facilitate reactions that require tighter TSs (with
different charge distributions) such as either substrate-assisted
phosphomonoesterase activity or phosphodiesterase activity. This is
again reflected in the fact that the discrimination between phophomono-
and diesterase activity is much larger when the enzyme is a native
phosphomonoesterase[53,54] than when it is a phosphodiesterase.In summary, our calculations demonstrate that catalyzing the hydrolysis
of phosphate monoester dianions with good leaving groups is far more
energetically demanding for an associative pathway than for a dissociative
one. However, the energy difference between the two pathways decreases
as the leaving group pKa increases, leading
to mechanistic ambiguity in the case of poor leaving groups. This
creates different mechanistic possibilities for the reactions of alkyl
phosphates and their corresponding enzyme-catalyzed reactions, as
both pathways are apparently plausible. Finally, detailed analysis
of the existing experimental data defines what is and can be known
from experimentation: direct kinetic characterization of these reactions
is not accessible, and so computational approaches are central to
understanding these reactions.
Figure 1
Figure 2
Figure 3
Figure 4
Figure 5