Alexei A. Neverov

Mechanistic studies of La3+- and Zn2+-catalyzed methanolysis of aryl phosphate and phosphorothioate triesters. Development of artificial phosphotriesterase systems

The methanolyses of a series of O,O-diethyl O-aryl phosphates (2,5) and O,O-diethyl S-aryl phosphorothioates (6) promoted by methoxide and two metal ion systems, (La3+)2(-OCH3)2 and 4:Zn2+:-OCH3 (4 = 1,5,9-triazacyclododecane) has been studied in methanol at 25 degrees C. Brønsted plots of the logk2 values vs. pKa for the phenol leaving groups give beta(lg) values of -0.70, -1.43 and -1.12 for the methanolysis of the phosphates and -0.63, -0.87 and -0.74 for the methanolysis of the phosphorothioates promoted by the methoxide, La3+ and Zn2+ systems respectively. The kinetic data for the metal-catalyzed reactions are analyzed in terms of a common mechanism where there is extensive cleavage of the P-XAr bond in the rate-limiting transition state. The relevance of these findings to the mechanism of action of the phosphotriesterase enzyme is discussed.

Metal-catalyzed alcoholysis reactions of carboxylate and organophosphorus esters

Publisher Summary This chapter elaborates the metal ion-catalyzed hydrolytic reactions of esters, amides, and organophosphorus esters. Apart from being fundamentally interesting and industrially important, phosphoryl and acyl transfer reactions are the key biological processes. Virtually, all the transition metal and lanthanide ions that have been investigated have some catalytic activity in promoting the transesterification of carboxylate esters and neutral phosphate esters. The early studies of metal-catalyzed acyl transfer reactions were predicated on the idea that a reduced polarity/dielectric constant medium would allow one to better realize the catalytic potential of the metal ion by reducing the tightness of the solvation shell around the metal ion and its constituents, as well as allow a stronger interaction energy with substrate. Despite a great deal of effort that has led to an increased understanding of how enzymatic catalysis might occur, it is generally held that none of the several models so far described approaches the enormous catalytic efficiency of natural enzymes. The ideas being discussed in this chapter will spur further work using the multiple effects of structure and medium to bring us closer to understanding the ways, in which nature performs such transformations.

Investigation of the effect of oxy bridging groups in dinuclear Zn(II) complexes that catalyze the cleavage of a simple phosphate diester RNA analogue.

Two sets of dinuclear Zn(II) complexes were prepared to determine the effect of the presence of oxyanionic bridging groups between the metal centers on the catalytic activity toward the methanolysis of the RNA analogue 2-hydroxypropyl-4-nitrophenyl phosphate (HPNPP, 2). The Zn(II)2 complexes of bis(di-(2-pyridylmethyl)amino)-m-xylene (6) and 2,6-bis(di-(2-pyridylmethyl)amino)-4-methylphenol (7) were compared to assess the effect of a bridging phenoxide ligand, while the Zn(II)2 complex of 1,3-bis-N1-(1,5,9-triazacyclododecyl)-propan-2-ol (8) was prepared to determine the effect of the 2-propoxy group compared to the previously studied complex of 1,3-bis-N1-(1,5,9-triazacyclododecyl)-propane (4). Detailed kinetic studies of the cleavage of 2 including k(obs) vs [catalyst] plots and (s)(s)pH-rate profiles were performed for each system along with potentiometric titration experiments to determine the acid dissociation constants for the catalytically relevant groups. The results show that inclusion of the phenoxy bridging group in 7:Zn(II)2 reduces the second-order catalytic rate constant (k2(cat)) for cleavage of 2 by a factor of 160 relative to that of 6:Zn(II)2, while the incorporation of a propoxy group in 8:Zn(II)2 reduces its efficacy by 3.7 x 10(4) times relative to 4:Zn(II)2. Energetics calculations reveal that 6:Zn(II)2 offers a 3.7 kcal/mol greater stabilization of the reaction transition state for the cleavage of 2 than does 7:Zn(II)2 and that 4:Zn(II)2 affords 6.5 kcal/mol greater transition state stabilization than does 8:Zn(II)2. The analyses show that the reduction in the transition state stabilization experienced with the complexes having permanently bridging oxyanion groups stems almost entirely from a weaker binding of the phosphate and catalyst, and a reduced catalytic rate constant. These results indicate that the presence of a bridging oxyanion ligand between the metal centers, a common structural element required for the successful formation of many small molecule dinuclear catalysts that show cooperative activity in water, significantly impairs the catalytic efficiency for cleavage of 2.

Cu(II)-Mediated decomposition of phosphorothionate PS pesticides. Billion-fold acceleration of the methanolysis of fenitrothion promoted by a simple Cu(II)–ligand system

The kinetics of methanolysis of the title compound (3) were studied in the presence of Cu(2+), introduced as Cu(OTf), in the presence of 0.5-1.0 eq. of methoxide and in the presence of 1.0 eq. of a ligand such as bipyridyl (5), phenanthroline (6) or 1,5,9-triazacyclododecane (4). In all cases the active species involve Cu(2+)((-)OCH(3)). In the case of added strong-binding ligands 5 or 6, a plot of the observed rate constant for methanolysis of 3 vs. [Cu(2+)](total) gives a curved line modelled by a process having a [Cu(2+)](1/2) dependence consistent with an active monomeric species in equilibrium with an inactive dimer i.e.[LCu(2+)((-)OCH(3))](2) <==> 2LCu(2+)((-)OCH(3)). In the case of the added strong binding ligand 4, the plot of the observed rate constant for methanolysis of 3 vs.[Cu(2+)](total) gives a straight line consistent with the catalytically active species being Cu(2+)(OCH(3)) which shows no propensity to form inactive dimers. Turnover experiments where the [3] > [Cu(2+)](total) indicate that the systems are truly catalytic. In the optimum case a catalytic system comprising 1 mM of the complex 4Cu(2+)((-)OCH(3)) catalyzes the methanolysis of 3 with a t(1/2) of approximately 58 s accounting for a 1.7 x 10(9)-fold acceleration relative to the background reaction at near neutral (s)(s)pH (8.75).

Potentiometric titration of metal ions in methanol

The potentiometric titrations of Zn2+, Cu2+ and 12 Ln3+ metal ions were obtained in ethanol to determine the titration constants (defined as the at which the [-OEt]/[Mx+]t ratios are 0.5, 1.5, and 2.5) and in two cases (La3+ and Zn2+) a complete speciation diagram. Several simple monobasic acids and aminium ions were also titrated to test the validity of experimental titration measurements and to establish new constants in this medium that will be useful for the preparation of buffers and standard solutions. The dependence of the titration constants on the concentration and type of metal ion and specific counterion effects is discussed. In selected cases, the titration profiles were analyzed using a commercially available fitting program to obtain information about the species present in solution, including La3+ for which a dimer model is proposed. The fitting provides the microscopic values for deprotonation of one to four metal-bound ethanol molecules. Kinetics for the La3+-catalyzed ethanolysis of paraoxon as a function of are presented and analyzed in terms of La3+ speciation as determined by the analysis of potentiometric titration curves. The stability constants for the formation of Zn2+ and Cu2+ complexes with 1,5,9-triazacyclododecane as determined by potentiometric titration are presented.

Biomimetic Cleavage of RNA Models Promoted by a Dinuclear Zn(II) Complex in Ethanol. Greater than 30 kcal/mol Stabilization of the Transition State for Cleavage of a Phosphate Diester

The cleavage of a series of seven substituted aryl 2-hydroxypropyl phosphates (1a-g) promoted by a dinuclear Zn(II) complex (3:Zn(II)2:(-OCH2CH3)) was investigated in ethanol at pH 9.0 +/- 0.2 and 25 degrees C. The kinetics for appearance of the product phenols follow very strong saturation behavior for all substrates where the dissociation constant of the bound complex has an upper limit of Km = 3 x 10(-7) M and the k(cat)(max corr.) values (corrected for triflate inhibition) range from 168 to 3 s(-1). A partial s(s)pH/log k(cat)(max corr). profile for the 3:Zn(II)2:(-OCH2CH3)-catalyzed reaction of le (3-methoxyphenyl 2-hydroxypropyl phosphate) is bell-shaped, plateauing from 7.9-10, and is fit to a two kinetically important ionizations having s(s)pKa values of 7.22 and 10.9. The Brønsted plot of log (k(cat)(max corr.)) vs. the s(s)pKa values for the phenols shows a break at about 14.3 with two beta(lg), values of -1.12 and 0.0. This is analyzed in terms of a change in rate limiting step from cleavage of the phosphate to a conformational change where the binding of the phosphate changes from one P-O- ----Zn(II) interaction to a Zn(II)----O-P-O---Zn(II) double activation. An energetics calculation comparing the ethoxide promoted cleavage of 1a-g with the 3:Zn(ll)2:(-OEt) promoted reaction indicates that the complex, 3:Zn(II)2, stabilizes the ethoxide plus substrate transition state for the cleavage of 1a-g by between 33 and 36 kcal/mol. The origins of the large stabilization are discussed in terms of the effect of the medium on the various rate and equilibrium constants involved.

Cu(II)-promoted methanolysis of N,N-dipicolylacetamide. multistep activation by decoupling of > ̈̈N-C═O resonance via Cu(II)-N binding, delivery of the Cu(II):((-)OCH3) nucleophile, and metal ion assistance of the departure of the leaving group.

The methanolysis of the Cu(II) complex of N-acetyl-N,N-bis(2-picolyl)amine (2) was investigated by a kinetic study as a function of pH in methanol at 25 °C and computationally by DFT calculations. The active species is the basic form of the complex (3(-)), or (1:Cu(II))((-)OCH(3))(HOCH(3))), and the rate constant for its solvolysis is k(max) = 1.5 × 10(-4) s(-1). The mechanism involves Cu(II) binding to the amide N lone pair, decoupling it from >N-C═O resonance, concomitant with Cu(II):((-)OCH(3)) delivery to the adjacent >N-C═O unit, followed by Cu(II)-assisted departure of the N,N-bis(2-picolyl)amide from a tetrahedral intermediate.

Leaving Group Assistance in the La3+-Catalyzed Cleavage of Dimethyl (o-Methoxycarbonyl)aryl Phosphate Triesters in Methanol

The catalytic methanolysis of a series of dimethyl aryl phosphate triesters where the aryl groups contain an o-methoxycarbonyl (o-CO2Me) substituent (4a-i) was studied at 25 degrees C in methanol containing La3+ at various concentrations and (s)(s)pH. Determination of the second-order rate constant for La3+(2)-catalyzed cleavage of substrate 4a (dimethyl (o-methoxycarbonyl)phenyl phosphate) as a function of (s)(s)pH was assessed in terms of a speciation diagram that showed that the process was catalyzed by La3+(2)(-OCH3)x dimers, where x = 1-5, that exhibit only a 5-fold difference in activity between all the species. The second-order catalytic rate constants (k2(La)) for the catalyzed methanolysis of 4a-i at (s)(s)pH 8.7 fit a Brønsted relationship of log k2(La) = (-0.82 +/- 0.11)(s)(s)pKa(lg) + (11.61 +/- 1.48), where the gradient is shallower than that determined for a series of dimethyl aryl phosphates that do not contain the o-CO2Me substituent, log k2(La) = (-1.25 +/- 0.06)(s)(s)pKa(lg) + (16.23 +/- 0.75). Two main observations are that (1) the o-CO2Me group preferentially accelerates the cleavage of the phosphate triesters with poor leaving groups relative to those with good leaving groups and (2) it provides an increase in cleavage rate relative to those of comparable substrates that do not have that functional group, e.g., k2(La)(dimethyl o-(methoxycarbonyl)phenyl phosphate)/k2(La)(dimethyl phenyl phosphate) = 60. Activation parameters for the La3+(2)-catalyzed methanolysis of 4a and dimethyl 4-nitrophenyl phosphate show respective DeltaH(double dagger) (DeltaS(double dagger)) values of 3.3 kcal/mol (-47 cal/mol x K) and 0.7 kcal/mol (-46.5 cal/mol x K). The data are analyzed in terms of a concerted reaction where the catalytic complex (La3+(2)(-OCH3)(x-1)) binds to the three components of a rather loose transition state composed of a nucleophile CH3O-, a nucleofuge -OAr, and a central (RO)2P(2+)-O(-) in a way that provides leaving group assistance to the departing aryloxy group.

Mechanistic studies of La3+ and Zn2+-catalyzed methanolysis of O-ethyl O-aryl methylphosphonate esters. An effective solvolytic method for the catalytic destruction of phosphonate CW simulants

The kinetics of methanolysis of six O-ethyl O-aryl methylphosphonates (6a-f) promoted by methoxide, La3+ and 1,5,9-triazacyclododecane complex of Zn2+(-OCH3) (5:Zn2+(-OCH3)) were studied as simulants for chemical warfare (CW) agents, and analyzed through the use of Brønsted plots. The beta(lg) values are, respectively, -0.76, -1.26 and -1.06, pointing to significant weakening of the P-OAr bond in the transition state. For the metal-catalyzed reactions the data are consistent with a concerted process where the P-OAr bond rupture has progressed to the extent of 84% in the La3+ reaction and ca. 70% in the Zn2+ catalyzed reaction. The catalysis afforded by the metal ions is remarkable, being about 10(6)-fold and 10(8)-fold for poor and good leaving groups, respectively, relative to the background reactions at pH 9.1. Solvent deuterium kinetic isotope studies for two of the substrates promoted by 5:Zn2+(-OCH3) give kH/kD = 1.0 +/- 0.1, consistent with a nucleophilic mechanism. A unified mechanism for the metal-catalyzed reactions is presented which involves pre-equilibrium coordination of the substrate to the metal ion followed by intramolecular delivery of a coordinated methoxide.

Mechanistic and computational study of a palladacycle-catalyzed decomposition of a series of neutral phosphorothioate triesters in methanol.

The methanolytic cleavage of a series of O,O-dimethyl O-aryl phosphorothioates (1a−g) catalyzed by a C,N-palladacycle, (2-[N,N-dimethylamino(methyl)phenyl]-C1,N)(pyridine) palladium(II) triflate (3), at 25 °C and sspH 11.7 in methanol is reported, along with data for the methanolytic cleavage of 1a−g. The methoxide reaction gives a linear log k2−OMe vs sspKa (phenol leaving group) Brønsted plot having a gradient of βlg = −0.47 ± 0.03, suggesting about 34% cleavage of the P−OAr bond in the transition state. On the other hand, the 3-catalyzed cleavage of 1 gives a Brønsted plot with a downward break at sspKa (phenol) 13, signifying a change in the rate-limiting step in the catalyzed reaction, with the two wings having βlg values of 0.0 ± 0.03 and −1.93 ± 0.06. The rate-limiting step for good substrates with low leaving group sspKa values is proposed to be substrate/pyridine exchange on the palladacycle, while for substrates with poor leaving groups, the rate-limiting step is a chemical one with extensive cleavage of the P−OAr bond. DFT calculations support this process and also identify two intermediates, namely, one where substrate/pyridine interchange has occurred to give the palladacycle coordinated to substrate through the S═P linkage and to methoxide (6) and another where intramolecular methoxide attack has occurred on the P═S unit to give a five-coordinate phosphorane (7) doubly coordinated to Pd via the S− and through a bridging methoxide linked to P and Pd. Attempts to identify the existence of the phosphorane by 31P NMR in a d4-methanol solution containing 10 mM each of 3, trimethyl phosphorothioate (a very slow cleaving substrate), and methoxide proved unsuccessful, instead showing that the phosphorothioate was slowly converted to trimethyl phosphate, with the palladacycle decomposing to Pd0 and free pyridine. These results provide the first reported example where a palladacycle-promoted solvolysis reaction exhibits a break in the Brønsted plot signifying at least one intermediate, while the DFT calculations provide further insight into a more complex mechanism involving two intermediates.