How can aprotic ionic liquids affect enzymatic enantioselectivity ?

The enantioselectivity of α-chymotrypsin in the esterification of N-acetyl-tryptophan with ethanol was examined in aprotic ionic liquids. The enantioselectivity was found to be strongly affected by a kind of solvent, water content, and reaction temperature. The (kcat/KM)L/(kcat/KM)D ratio in 1-ethyl-3-methylimidazolium bis(fluorosulfonyl)imide ([C2mim][FSI]) containing 1.0% (v/v) water at 25 ̊C exhibits 32,000, while that in 1-ethyl-3-methylimidazolium tetrafluoroborate ([C2mim][BF4]) containing 1.0% (v/v) water at 25 ̊C shows 190. The (kcat/KM)L/(kcat/KM)D ratio in [C2mim] [BF4] at 25 ̊C varies from 190 at 1.0% (v/v) water to 65000 at 5.0% (v/v) water. Moreover, the (kcat/KM)L/ (kcat/KM)D ratio in [C2mim][FSI] containing 5.0% (v/v) water can be forced to induce a 7-fold increase simply by switching from 25 ̊C to 40 ̊C. The enantioselectivity tended to correlate with enzyme reactivity in ionic liquids.


INTRODUCTION
Enantioselective synthesis is a key process in modern chemistry, and is particularly important in the field of pharmaceuticals, as the different enantiomers or diastereomers of a molecule often have different biological activities.Therefore, the enantioselectivity is the most valuable feature of enzymes from the standpoint of their application as practical catalysts.In nonaqueous reaction system, the enantioselectivity of enzymes has been markedly dependent upon organic solvents [1][2][3][4][5].On the other hand, enzymatic reactions in hydrophilic solvents have the advantage of the solubility of a variety of substrates, including amino acid derivatives, which are poorly solu-ble in hydrophobic solvents [5].However, when a hydrophilic solvent is used as a reaction medium, the enzyme molecule directly contacts with the solvent, and thereby its activity and enantioselectivity are strongly influenced by the nature of the solvent [1,2].Moreover, as the enzyme is insoluble in nonaqueous media, which are 100% organic solvent media or aqueous solutions containing high amount of organic solvents, and is suspended, the reactivity of enzymes tends to be strongly influenced by the dispersion state of enzymes.
Ionic solvent that is liquid at room temperature has attracted increasing attention as innovative non-aqueous media for the chemical processes because of the lack of vapor pressure, the thermal stability, and the high polarity [6].Chemical and physical properties of ionic liquids can be changed by the appropriate modification of organic cations and anions, which are constituents of ionic liquids.Biotransformation in ionic liquids has extensively been studied [6,7].In our previous study, we have reported that protease-catalyzed esterification of amino acid and peptide synthesis are highly enhanced in ionic liquids, compared to organic solvents [8,9].
In the present study, we have addressed a question how aprotic ionic liquids can affect the enantioselectivity of enzymatic esterification.We have examined proteasecatalyzed esterification of N-acetylated amino acid with ethanol in partially or perfectly water-miscible ionic liquids.We employed bovine pancreas α-chymotrypsin as a model enzyme, since it is well investigated regarding its structure, functions, and properties [10].

Kinetic Measurements
The standard reaction for esterification synthesis was carried out as follows: Five hundred micro liter of ionic liquid or organic solvent containing a given amount of water, 5 -25 mM N-Ac-L-Trp-OH or 5 -25 mM N-Ac-D-Trp-OH, 1000 mM ethanol, and 74 mM acetanilide was added to 1 mg of α-chymotrypsin in a 4 mL screwcap vial.The vial was shaken at 120 rpm and 25˚C.The amounts of the reaction components were determined with HPLC (Shimadzu LC-10A) ( Shimadzu Co., Kyoto, Japan) using a TSK-GEL ODS-80TM column (Tosoh Co., Tokyo, Japan) eluted with water-methanol (5:5 by volume) at 1.0 mL/min with detection at 290 nm.Acetanilide was used as an internal standard.

Effect of Reaction Medium on α-Chymotrypsin-Catalyzed Esterification
In the present work, α-chymotrypsin-catalyzed esterification was examined as shown in Figure 2. The esterification obeys ping-pong kinetics [11,12] where E and E•Ac-Trp-OH are α-chymotrypsin and enzyme-substrate complex, respectively.Similarly, the rates of E, enzyme-subatrate complex (E•Ac-Trp-OH ), acyl enzyme intermediate (Ac-Trp-E), acyl enzyme-ethanol complex (Ac-Trp-E•EtOH), H 2 O, and N-acetyl-tryptophan ethyl ester (Ac-Trp-OEt) are as follows: Since all enzyme present is either free or complexed, where [E] 0 is the total concentration of enzyme in the system.Assuming the steady state approximation on the rate of E•Ac-Trp-OH, from Eq.3 where Ks 1 is the dissociation constant of EtOH Assuming the steady state approximation on the rate of Ac-Trp-E•EtOH, from Eq.5 The reaction rate v is where Ks 2 is the dissociation constant of Ac-Trp-E•EtOH.From Eq.13 where Thus, the reaction rate v corresponds upon Michaelis-Menten type model.Substituting Eqs.11 and 14 into Eq.15, Substituting Eq.16 into Eq.10, The performances of enzymes such as activity and specificity in non-aqueous media markedly depend upon the nature of solvents [1,2].In order to assess the effect of reaction media on kinetic parameters of α-chymotrypsin, the reaction rate in ionic liquids and organic solvents containing 5%   v v water was measured at different concentrations of N-Ac-L-Trp-OEt or N-Ac-D-Trp-OEt at 25˚C.The kinetic parameters, k cat and K M , were derived by correlating resultant reaction rates with Hanes-Woolf plot [12].Table 1 shows kinetic parameters in ionic liquids and THF.Since the magnitude of k cat in the esterification of natural substrate N-Ac-L-Trp-OH with EtOH was much greater than that in the esterification of non-natural substrate N-Ac-D-Trp-OH with EtOH, the  The enzyme was placed in the solvent containing 5% (v/v) water, 5 -25 mM N-Ac-Trp-OH, and 1000 mM EtOH, and the resulting mixture was shaken at 120 rpm and 25˚C.The reaction rates of ester formation were measured, and kinetic parameters were derived by correlating resultant reaction rates with Hanes-Woolf plot.
specificity constant cat M k K of L isomer was larger than that of D isomer.This result indicates that the enantiopreferance of α-chymotrypsin in ionic liquids and THF is similar to that in aqueous solutions.The  cat M  k K L in [C 2 mim][BF 4 ] system was greatest regarding reaction systems used in the present work.We have reported that [C 2 mim][BF 4 ] has little denaturation effect on proteins in aqueous media, and exhibits high thermal stabilization and refolding effects on proteins [13].Moreover, inspecttion of Table 1 reveals that the enantioselectivity, expressed as     c a t M c a t M L D , can be forced to span a 325-fold range simply by switching from one ionic liquid to another under otherwise identical conditions.

Effect of Water Content on Enantioselectivity of α-Chymotrypsin in Ionic Liquids
A common thread in all studies of enzymes in anhydrous solvents is that the amount of water associated with the enzyme is a key determinant of the properties (e.g.activity, stability, and specificity) that the enzyme exhibits [1].Moreover, water can act as a substrate in reactions using hydrolytic enzymes.In order to elucidate the relationship between the enantioselectivity of α-chymotrypsin and water content in ionic liquids, the (k cat /K M ) L /(k cat /K M ) D ratio was investigated at different water contents and 25˚C.When a certain amount of water is added into the nonaqueous enzymatic reaction system, some water is bound to the enzyme, and thereby has a large influence on the enzyme performance, while the other amount of water is dissolved in the solvent [1].Water associated with the enzyme activates the enzyme by increasing the internal flexibility of the enzyme molecule, since water acts as a plasticizer to increase the flexibility [14].The optimum water content for the enzyme performance is due to the balance between kinetic rigidity and thermodynamic stability of enzyme structures, and is called essential water [15].The kinetic rigidity is relaxed by increasing water content, while native enzyme structure gradually changes through thermodynamic stability.For instance, the activity increases with an increase in the flexibility of rigid enzyme in ionic liquids, and it decreases with an increase in disturbance of enzyme structure [9].[BF 4 ] and THF are water soluble.

Effect of Reaction Temperature on Enantioselectivity of α-Chymotrypsin in Ionic Liquids
Enzymatic reactions, as well as chemical reactions, obey the Arrhenius correlation between reaction rate constant and temperature, although the temperature range is quite limited.Accordingly, it is considered that the enantioselectivity is strongly influenced by the reaction temperature.In order to estimate the effect of reaction temperature on α-chymotrypsin-catalyzed esterification in ionic liquids, the enantioselectivity in ionic liquids and THF containing 5%   v v water was investigated at different temperatures.Figure 4 shows the enantioselectivity of α-chymotrypsin in the esterification of N-Ac-Trp-OH with EtOH in ionic liquids and THF at different reaction temperatures.The enantioselectivity of α-chymotrypsin in [C 2 mim][BF 4 ] at 40˚C was lower than that at 25˚C, while that in [C 2 mim][FSI] increased with increasing the reaction temperature.On the other hand, the enantioselectivity of α-chymotrypsin in THF dropped with an increase in the reaction temperature.The temperature dependence of the enantioselectivity of protease and lipase is markedly affected by organic solvents [3].Thus, the result indicates that the temperature dependence of the enantioselectivity is controlled by changing the reaction medium from one ionic liquid to another, similar to the case of organic solvents.

Relation between the Reactivity and Enantioselectivity of α-Chymotrypsin in Ionic Liquids
As mentioned above, the enantioselectivity is strongly influenced by ionic liquids, water content, and reaction temperature.In order to assess the correlation between the enzyme reactivity and the enantioselectivity, the k K L is attributable to the enzyme structure [11].Therefore, the higher the native structure of en-

CONCLUSION
We have demonstrated that α-chymotrypsin exhibits the wide enantioselectivity in the esterification of N-Ac-Trp-OH with ethanol in ionic liquids.The kind of ionic liquids strongly affected the enantioselectivity of αchymotrypsin.The enantioselectivity of α-chymotrypsin markedly depended upon the water content in [C 2 mim] [BF 4 ] and [C 2 mim] [FSI], similar to THF.When the water content was 5%   v v , the enantioselectivity in [C 2 mim][BF 4 ] was much superior to that in THF.The temperature dependence of enantioselectivity was remarkably influenced by ionic liquids.These results indicate that the enantioselectivity can finely be controlled by selected conditions in ionic liquids.

Figure 1 .
Figure 1.Structures of solvents used in the present work.

Figure 3
shows the enantioselectivity of α-chymotrypsin in the esterification of N-Ac-Trp-OH with EtOH in ionic liquids and THF at different water contents.The enantioselectivity of α-chymotrypsin in [C 2 mim][BF 4 ] increased with an increase in water content, while that in [C 2 mim][FSI] decreased with increasing water content.

Figure 3 .
Figure 3.Effect of water content on the enantioselectivity of α-chymotrypsin in the esterification of N-Ac-Trp-OH with EtOH in [C 2 mim][BF 4 ], [C 2 mim] [FSI], and THF.The enzyme was placed in the solvent containing a certain amount of water, 5 -25 mM N-Ac-Trp-OH, and 1000 mM EtOH, and the resulting mixture was shaken at 120 rpm and 25˚C.

 5 .
cat M  k K L value, as seen in Figure One can observe an increase in the  cat M  k K L value.The specificity con- stant  cat M 

Figure 4 .
Figure 4. Effect of reaction temperature on the enantioselectivity of α-chymotrypsin in the esterification of N-Ac-Trp-OH with EtOH in [C 2 mim][BF 4 ], [C 2 mim][FSI], and THF.The enzyme was placed in the solvent containing 5% (v/v) water, 5 -25 mM N-Ac-Trp-OH, and 1000 mM EtOH, and the resulting mixture was shaken at 120 rpm and 25 and 40˚C.

Table 1 .
Kinetic parameters of α-chymotrypsin in esterification in various solvents a .
Since the water solubility of [C 2 mim][FSI] is much lower than that of [C 2 mim][BF 4 ], the distribution of water to the enzyme molecule in [C 2 mim][FSI] is superior to that in [C 2 mim] [BF 4 ].Consequently, at 5% (v/v) water the disturbance of enzyme structure might be enhanced to some extent in [C 2 mim][FSI] system, since the water solubility of [C 2 mim] [FSI] is 3.45%.On the other hand, [C 2 mim][BF 4 ] system exhibited the same tendency in the relation between the water content and the enantioselectivity as THF system.[C 2 mim][BF 4 ] and THF systems was probably in the relax of kinetic rigidity at 5% v v water, since [C 2 mim]