Báo cáo khoa học: Do N-terminal nucleophile hydrolases indeed have a single amino acid catalytic center? Supporting amino acid residues at the active site of penicillin G acylase pptx

It is shown that the main chain car-bonyl group of GlnB23 forms a hydrogen bond with the leaving group nitrogen, thus influencing the hydrolysis rate.. Substrate binding causes considerab

a single amino acid catalytic center?

Supporting amino acid residues at the active site of penicillin

G acylase

Diana Zhiryakova1, Ivaylo Ivanov2, Sonya Ilieva3, Maya Guncheva1, Boris Galunsky4and

Nicolina Stambolieva1

1 Institute of Organic Chemistry with Center of Phytochemistry, Bulgarian Academy of Sciences, Sofia, Bulgaria

2 Faculty of Biology, University of Sofia ‘Sv Kl Ohridski’, Bulgaria

3 Faculty of Chemistry, University of Sofia ‘Sv Kl Ohridski’, Bulgaria

4 Institute of Technical Biocatalysis, Hamburg University of Technology, Germany

The N-terminal nucleophile (Ntn) hydrolase

superfam-ily comprises enzymes sharing a characteristic

organi-zation of the secondary structure in the catalytic

domain, despite the very low sequence homology [1,2]

The reaction mechanism that is suggested to be com-mon for all Ntn hydrolases resembles that of serine proteases, involving consecutive enzyme acylation and deacylation steps A feature of the catalytic mechanism

Keywords

catalytic mechanism; Hammett plot;

N-terminal nucleophile (Ntn) hydrolase;

penicillin G acylase; quantum mechanical

(QM) and molecular mechanical (MM)

modeling

Correspondence

D Zhiryakova, Institute of Organic

Chemistry with Center of Phytochemistry,

Bulgarian Academy of Sciences, 9 Acad.

G Bonchev str., 1113 Sofia, Bulgaria

Fax: +359 2 870 0225

Tel: +359 2 9606 160

E-mail: diana_zh@yahoo.com

(Received 25 September 2008, revised 28

January 2009, accepted 27 February 2009)

doi:10.1111/j.1742-4658.2009.06987.x

A new set of experimental kinetic data on the hydrolysis of a series of phenylacetyl p-substituted anilides catalyzed by penicillin G acylase from Escherichia coli (PGA) is presented in this article The Hammett plot of log(kcat,R⁄ kcat,H) versus rp) has three linear segments, which distinguishes the enzyme from the other N-terminal nucleophile hydrolases for which data are available Three amino acids in the vicinity of the catalytic SerB1 (AsnB241, AlaB69, and GlnB23) were included in the quantum mechanical model The stable structures and the transition states for acylation were optimized by molecular mechanical modeling and at the AM1 level of the-ory for three model substrates (with H, a methoxy group or a nitro group

in the para position in the leaving group) Intrinsic interactions of several functional groups at the active site of PGA are discussed in relation to the catalytic efficiency of the enzyme The energy barrier computed for the first step of acylation (the nucleophilic attack of SerB1) is lower than that for the second step (the collapse of the tetrahedral intermediate) However, the electronic properties of the substituent on the leaving group affect the structure of the second transition state It is shown that the main chain car-bonyl group of GlnB23 forms a hydrogen bond with the leaving group nitrogen, thus influencing the hydrolysis rate On the basis of our computa-tions, we propose an interpretation of the complex character of the Ham-mett plot for the reaction catalyzed by PGA We suggest a modified scheme of the catalytic mechanism in which some of the intramolecular interactions essential for catalysis are included

Abbreviations

AE, acyl enzyme; AGA, aspartylglucosaminidase; ES, enzyme–substrate; GGT, c-glutamyl transpeptidase; MM, molecular mechanical; Ntn, N-terminal nucleophile; PGA, penicillin G acylase from Escherichia coli; QM, quantum mechanical; TI, tetrahedral intermediate;

TS, transition state.

of Ntn hydrolases is that the nucleophile (side chain

hydroxyl or thiol group), which attacks the carbonyl

carbon of the scissile amide bond, and the general

base, which accepts the proton from the nucleophile,

belong to the same N-terminal amino acid residue

(Ser, Thr, or Cys) The N-terminal nucleophile is

engaged in a hydrogen bond network, which has

stabi-lizing and activating functions in addition to

maintain-ing the proper spatial structure of the active site [3–5]

Therefore, the catalytic efficiency of Ntn hydrolases

strongly depends on intrinsic interactions within the

reaction intermediates A deeper understanding of the

catalytic mechanism requires knowledge of the

contri-butions of the supporting, ‘catalytically insignificant’

amino acids to the energetics of the reaction

The present article is focused on the hydrolytic

reac-tion catalyzed by penicillin G acylase from Escherichia

coli (PGA; EC 3.5.1.11) PGA is widely used for

hydrolytic and synthetic transformations in

laboratory-scale organic synthesis and in the industrial production

of semisynthetic b-lactam antibiotics [6–9] The enzyme

is one member of the Ntn superfamily, which is

struc-turally very well characterized Much information has

been accumulated from crystallographic and kinetic

studies, as well as from site-directed mutagenesis [10–

14] The mature PGA is a periplasmic 86 kDa

hetero-dimer of A and B chains (209 and 557 amino acids,

respectively) The side chain hydroxyl of the

N-termi-nal SerB1 was identified as the attacking nucleophile

Its specificity is determined mainly by the acyl moiety

of the substrate: phenylacetyl derivatives have the

low-est Km values In contrast, the leaving group can

vary from ammonia to 6-aminopenicillanate through a

wide range of compounds with a primary amino or

hydroxyl group

Here we present a new set of kinetic data on the

PGA-catalyzed hydrolysis of a series of phenylacetyl

p-substituted anilides (Scheme 1) For the

interpreta-tion of the experimental results, a quantum mechanical

(QM) model of the enzyme active site was constructed

It illustrates the reorganization of the hydrogen bond

network at the active site, which predetermines the

cat-alytic transformations Several functional groups in the

proximity of SerB1 were assigned probable roles in

catalysis

Results and Discussion

The results of the kinetic experiments are presented in Table 1 All substrates have Michaelis constants of the same order of magnitude This confirms an earlier con-clusion, that the p-substituent on the leaving group influences the reaction rate by its electronic properties and does not affect substrate binding (Fig S1) [15]

On the other hand, the hydrolysis rate varies with the substituent on the amino moiety of the substrate, con-firming that the formation of acyl enzyme (AE) is the rate-limiting step of the reaction The Hammett plot of log(kcat,R⁄ kcat,H) versus rp)is shown in Fig 1 No cor-relation was observed between the rate constant and the van der Waals volume, the Taft steric parameter,

or the hydrophobic parameter of the substituent R The Brønsted plots of log(kcat,R⁄ kcat,H) versus pKa,1 and pKa,2of the leaving aniline are given in Fig S2 The Hammett plot can be divided into three linear segments: the points corresponding to substrates with electron-donating substituents (R = CH3or OCH3) lie

on a line with a negative slope q = ) 2.95 ± 0.98; for substrates with moderate electron-withdrawing substit-uents (R = Br, CF3, COOC2H5 or COCH3) the slope

is positive q = 0.90 ± 0.10; surprisingly, substrates with R = CN or NO2 lie on a line with a negative slope q =)0.50 ± 0.18 The dependence of the rate

on the electronic factor of the substituent for the PGA-catalyzed hydrolytic reaction is very distinct as compared with the other Ntn hydrolases for which data are available [16,17] The Hammett plot of the transpeptidation reaction catalyzed by c-glutamyl transpeptidase (GGT; EC 2.3.2.2), is biphasic, displaying a negative slope for the electron-donating substituents (q =)1.3) and a positive slope for the electron-withdrawing substituents (q = 0.4) The gly-cosylasparaginase-catalyzed hydrolysis [aspartylgluco-saminidase (AGA), EC 3.5.1.26] is also characterized

by a biphasic dependence: substrates with electron-donating groups give a line with slope q =)0.94, and substrates with electron-withdrawing groups give a line with slope q = 0.70 For all three enzymatic reactions (GGT-catalyzed transpeptidation, and AGA-catalyzed and PGA-catalyzed hydrolysis), acylation is the rate-limiting step [16–18] However, the values of q for

Scheme 1 PGA-catalyzed hydrolysis of a series of phenylacetanilides.

PGA are higher than those reported for

glycosylaspar-aginase and GGT, indicating that the PGA-catalyzed

hydrolysis is much more sensitive to the electronic

properties of the substituent on the leaving group The

third segment, corresponding to strong acceptor

groups on the leaving aniline of the substrate,

repre-sents a substantial difference and a key feature of the

PGA catalytic reaction It is probably a cumulative result of intrinsic amino acid interactions in the active site of the E coli enzyme that differentially (de)stabi-lize the structures along the reaction pathway

The interpretation of the presented kinetic results requires a more sophisticated QM model that would most adequately and yet economically reflect the inter-actions at the PGA active site during catalysis Three residues in the vicinity of the N-terminal nucleophile were selected for the construction of the model: AsnB241, AlaB69, and GlnB23 AsnB241 proved to be indispensable for catalysis, as its mutation to Ala led

to a dramatic reduction of the catalytic activity, with a minor effect on proenzyme processing [11] AsnB241, together with the main chain amide of AlaB69, forms the oxyanion hole that balances the negative charge and thus lowers the energy of the reactive tetrahedral intermediate (TI) In addition, it contributes to correct positioning of the substrate against the catalytic SerB1 GlnB23 was also shown to interact with the nucleo-phile and the general base, and contribute to the stabilization of the TI [5,10] Table 2 presents data on the interatomic distances in the crystal structures of the wild-type enzyme, its complex with a competitive

Table 1 Kinetic parameters of the PGA-catalyzed hydrolysis of phenylacetyl p-substituted anilides Values of r p )are from [31] pK

a,1 refers

to the equilibrium H 3 N+Ar ¡ H 2 NAr + H+; pK a,2 refers to the second dissociation step, H 2 NAr ¡)HNAr + H+.

PhCH 2 CONHC 6 H 4 -pR

rp) pKa,1 pKa,2 kcat(s)1) Km(m M )

kcat⁄ K m

(m M )1Æs)1)

Substituent R Name of substrate

NO2 N-(4-Nitrophenyl)-2-phenylacetamide 1.27 1.02 18.9 16.7 ± 0.5 0.16 ± 0.01 104.4

COCH 3 N-(4-Acetylphenyl)-2-phenylacetamide 0.84 2.19 22.6 a 27.4 ± 0.8 0.20 ± 0.01 137.0 COOC2H5 Ethyl 4-[(phenylacetyl)amino]benzoate 0.75 2.38 21.6 ± 1.0 0.10 ± 0.01 216.0

CF3 2-Phenyl-N-[4-(trifluoro-methyl)-phenyl]acetamide 0.65 2.57 24.3 a 17.7 ± 1.6 0.35 ± 0.09 50.6

a For these substrates, pKa2values in water were not available They were calculated from those for dimethylsulfoxide, using a linear correla-tion [32].

–0.4 –0.2 0.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4

–0.2

0.0

0.2

0.4

0.6

0.8

1.0

O

NH

R

–NO

2

–CN

–COCH 3 –COO

2 CH 5

–CF 3

–Br –H

–OCH 3

–CH 3

σP –

Fig 1 Hammett plot for the hydrolysis of a series of phenylacetyl

p-substituted anilides catalyzed by PGA The insert shows the

general formula of the substrates.

Table 2 Interatomic distances in the crystal structures of wild-type PGA and the complexes with phenylacetic acid, penicillin G sulfoxide (PGSO), and its phenylmethanesulfonyl-serylB1 derivative.

Distance (A ˚ )

Ligand

Protein Data

NaGlnB23

–OcSerB1

OeGlnB23

–NaSerB1

OdAsnB241 –NaSerB1

OaGlnB23 –ligand

inhibitor, the complex with a slowly hydrolyzed

sub-strate, and the phenylmethanesulfonyl-SerB1

deriva-tive These structures are mimics of the stationary

points along the reaction pathway; they depict the

changes in the spatial structure of the active site during

catalysis Phenylacetic acid induces no essential change

in the conformation of the enzyme Substrate binding

causes considerable shortening of the hydrogen bonds

of the side chain hydroxyl of SerB1 with the backbone

amino group of GlnB23 and with the side chain

car-bonyl group of AsnB241 The main chain carcar-bonyl

group of GlnB23 closely interacts with the oxygen

atom in the locality of the nucleofuge in the structural

analog of the TI These experimentally obtained

data form the basis for the construction of our

model, which is described in detail in Experimental

procedures

The first stage of the catalytic cycle, enzyme

acyla-tion, proceeds via two steps separated by a relatively

stable intermediate, the TI The structures of the

enzyme–substrate (ES) complex, AE with free aniline,

the TI, and two transition states (TSs) were optimized

for the model substrate CH3CONHC6H5 in the

envi-ronment of the catalytic and the supporting amino

acids Table 3 presents the geometry parameters, which

undergo significant changes during catalysis, optimized

by AM1 and HF⁄ 6-31G** QM computations and

molecular mechanical (MM) modeling with the

Dreid-ing force field The initial Michaelis complex (ES)

fea-tures spatial approximation of the side chain of SerB1

to the carbonyl carbon of the substrate, which is

favor-able for nucleophilic attack (Tfavor-able 3 and Fig S3) The

Michaelis complex of penicillin G with PGA has a

similar structure, and is shown in Fig S4 In the TS

(TS1), which separates the ES complex from the TI, the proton transfer from the nucleophile to the general base is practically completed, and the bond between

Oc of SerB1 and the carbonyl carbon of the substrate

is partially formed The positive charge of the a-amino group of SerB1 in TS1 is stabilized by three hydrogen bonds: two with the side chain carbonyl oxygens of GlnB23 and AsnB241, and a bifurcate bond with its own side chain oxygen and the carbonyl oxygen of the substrate The hydrogen bond between the negatively charged Oc SerB1 and the main-chain NH of GlnB23 becomes stronger upon the nucleophilic attack The energy of the TI for acetanilide, estimated by AM1 computations, is 29.72 kcalÆmol)1relative to the energy

of the ES complex Its optimized structure is shown in Fig 2 The interactions with the oxyanion-hole resi-dues AsnB241 and AlaB69 strongly decrease the energy of the TI As our model shows, the oxyanion is also hydrogen-bonded to the positively charged a-amino group of SerB1, thus gaining additional sta-bilization The a-amino group of the aspartyl moiety

in b-N-acetylglucosaminyl-l-asparagine has a similar function in the AGA-catalyzed hydrolysis [3] Proba-bly, such additional stabilization by a protonated amino group in the proximity of the oxyanion can be found in the rest of the Ntn hydrolases [3] From another point of view, the hydrogen bond between the oxyanion and the aNH3+ of SerB1 resembles the one between the carboxylate group of the Asp residue and the protonated imidazole ring of the His residue in the serine protease catalytic triad In the second TS (TS2)

of the expulsion of the p-substituted aniline, the bond between the oxyanion and the protonated a-amino group of SerB1 is weaker than in TS1, allowing for

Table 3 Selected interatomic distances in the stationary points of the modeled PGA-catalyzed hydrolysis of acetanilide (R = H) and p-nitro-acetanilide (R = NO2) optimized by AM1 calculations.

Atoms a

Distance (A ˚ ) ES

R = H

TS1

R = H

TI

R = H

TI b

R = H

TI c

R = H

TS2

R = H

TS2

R = NO2

AE + H2NC6H5

R = H

Oc SerB1 M C 3.37 1.84 1.50 1.49 1.51 1.48 (1.47) 1.42 (1.42) 1.37

Oc SerB1 M NaGlnB23 3.04 2.92 3.01 3.1 2.68 3.02 3.07 3.12

Na SerB1 M OeGlnB23 4.36 2.92 2.85 2.88 3.00 3.00 2.90 3.04

NaSerB1M OdAsnB241 3.01 2.78 2.73 2.79 2.74 2.98 (2.86) 2.81 (2.78) 3.20

Na SerB1

NaSerB1M OcSerB1 2.97 2.80 2.94 2.85 2.86 2.97 (2.96) 2.97 (2.97) 2.94

a

If not designated otherwise, atoms belong to the former substrate.bFrom HF ⁄ 6-31G** QM calculations c

From MM calculations with the Dreiding force field Optimized geometry parameters without GlnB23 in the model are given in parentheses.

restoration of the carbonyl function The hydrogen

bonds of a-NH3+ of SerB1 with OeGlnB23 and

OdAsnB241 are elongated The protonated general

base is situated closer to the leaving group nitrogen

atom, and the proton transfer for the expulsion of the

aniline is in progress (general acid catalysis)

The untypical Hammett dependence observed for

the PGA-catalyzed hydrolysis of phenylacetyl anilides

indicates that a change in the reaction pathway or the

rate-limiting step occurs depending on the structure of

the substrate For the model substrate acetanilide, the

energy barrier computed for the first step (the

nucleo-philic attack of SerB1), is 32.34 kcalÆmol)1, relative to

the energy of the ES complex For the second step, the

barrier is 37.00 kcalÆmol)1, and this identifies the

col-lapse of the TI as the rate-limiting step of acylation

This is also true for the nitro-substituted and

methoxy-substituted acetanilides, as well as for a different type

of substrate – N-methylacetamide However, in the

lat-ter case, the two energy barriers are almost leveled, the

difference being only 2 kcalÆmol)1 The conclusions of

Menard et al on the transpeptidation reaction

cata-lyzed by GGT are similar [16], as are the calculations

of Galabov et al concerning the energetics of the

alka-line hydrolysis of N-phenylacetamides [19] The

investi-gation of Perakyla et al on the catalytic reaction of

AGA, however, predicts that, energetically, the highest

point in the acylation step is the nucleophilic attack on

the carbonyl carbon of the substrate [3] Our result

disagrees with the conclusion of Chilov et al., who

employed a different model system [20] The two

mod-els are in good agreement on the geometry of the

sta-tionary points on the potential energy surface of the

PGA-catalyzed hydrolysis However, they disagree on

the energetics of the reaction, most probably because

of the substitution of the oxyanion hole with two water molecules The effective stabilization of the oxy-anion is the main driving force of the first step of acyl-ation, and dominates all other electronic effects on the reaction center The model system presented here more closely reflects the structure and electron density distri-bution of the real substrates and PGA active site

In order to interpret the biphasic character of the Hammett plots available for AGA and GGT, it was suggested that the breakdown of the tetrahedral struc-ture proceeded via general acid catalysis, whereby the proton transfer to the nitrogen of the leaving group aniline occurs simultaneously with the C–N bond cleavage [17] Accordingly, the degree of proton trans-fer and C–N bond cleavage would both depend on the electronic nature of the p-substituent [16] Figure 3 shows the optimized structures of the second TSs of the PGA-catalyzed hydrolysis of acetanilide (R = H) and p-nitroacetanilide (R = NO2) As can be seen, the stabilizing interactions of the oxyanion with AsnB241, AlaB69 and the a-amino group of SerB1 become weaker in TS2; the carbonyl group of the substrate is partially restored, and the protonated general base is properly oriented to give a proton to the leaving group nitrogen (Table 2) In the case of R = H, the proton transfer is 40% complete, whereas the amidic C–N bond is cleaved to a very small degree The TS resem-bles the structure denoted TS2a in Fig 4 The partial positive charge on the nucleofuge nitrogen is stabilized

by hydrogen bonding with the main chain carbonyl oxygen of GlnB23 Removing this residue from the

QM model results in practically no change in the struc-ture of TS2 Energetically, its absence is partially com-pensated for by a stronger interaction of the aNH3+

of SerB1 with the oxyanion and with the side chain of

Fig 2 Optimized structures of the TI of

hydrolysis of acetanilide by QM calculations

at the AM1 level (A) and of

N,2-diphenyl-acetamide by Dreiding force field MM

modeling (B).

AsnB241 (Table 3) The calculations show that TS2

for R = OMe does not differ substantially in structure

from that of acetanilide However, as can be seen from

Fig 4, GlnB23 makes a significant contribution to the

protonation of the leaving group prior to its expulsion

The positive combination of the electronic factor of R

and the hydrogen bond between the leaving group

nitrogen atom and the main chain carbonyl oxygen of

GlnB23 is evidenced by the steep increase of hydrolysis

rate constant with the decrease of rp )for the

electron-donating substituents (R = CH3or OCH3) (Fig 1)

The second TS of acylation for p-nitroacetanilide

features a high degree of C–N bond cleavage and a

very low degree of protonation of the leaving group

(Fig 4) The aromatic system provides resonance stabilization of the partial negative charge on the nitrogen Electron-withdrawing substituents further decrease the energy of the stationary point Starting from R = H with the increase in the rp) value, TS2 shifts in the direction of TS2b, and the expulsion of an anilide anion is more favored The main chain car-bonyl group of GlnB23 can still be hydrogen-bonded

to the leaving group nitrogen (Fig 3) In the cases of

R = Br, CF3, COOC2H5 or COCH3, the resultant effect is a slow increase of the hydrolysis rate constant with an increase in rp), i.e a small value of q In comparison with the unsubstituted substrate, the absence of GlnB23 in the QM model has a greater

Fig 3 Optimized structures of the second

TS of hydrolysis of acetanilides with (A)

R = H and (B) R = NO 2 in the para position

in the leaving group The arrows on the TS structures indicate the reaction coordinate with an imaginary frequency.

C–N cleavage

N

H 3 +

O

H

N B n

R

O –

TI

NH 2

R

N

H 2

O

Bn

O

H 2 N

O

H

N + Bn

R

O –

N

H 3 +

O

Bn

O

H

N –

R

TS2b

AE

Fig 4 More O’Ferrall diagram for the brea-kdown of the TI of the PGA-catalyzed hydro-lysis of CH 3 CONHC 6 H 4 -pR with GlnB23 (circles) and without GlnB23 (triangles) in the constructed model Solid symbols,

R = H; gray symbols, R = OMe; open symbols, R = NO2.

effect on the structure of TS2 for p-nitroacetanilide.

The nucleofuge is protonated to a higher degree, and

the amidic C–N bond is a little shorter; the a-amino

group of SerB1 interacts closely with the oxyanion

(Fig 3) This indicates that GlnB23 promotes the

for-mation of an anilide ion Probably, the combination of

stronger resonance stabilization by the strong

electron-withdrawing groups (R = CN and NO2) and the

hydrogen bonding between the leaving group nitrogen

and the main chain carbonyl of GlnB23 leads to the

formation of a TS similar to TS2b The subsequent

protonation of the nucleofuge becomes the

rate-limit-ing step of enzyme acylation This is shown by the

negative slope of the third segment of the Hammett

plot for the strong electron acceptors

The small difference between the hydrolysis rates of

esters and amides of common acyl moieties is

evi-dence for the effect of GlnB23 at the active site of

PGA on the energetics of the reaction The values of

kcat for methyl 2-phenylacetate and 2-phenylacetamide

are 190 and 50 s)1, respectively For both substrates,

acylation is rate-limiting, as the rate constant of

deac-ylation is over 1000 s)1 [18] For comparison, AGA

hydrolyzes the b-methyl ester of Asp faster than the

amide (Asn), the rate constants differing by several orders of magnitude [21] The leaving alcohol⁄ alcox-ide group cannot form a hydrogen bond with the main chain carbonyl of GlnB23 Most probably, the repulsion between the two oxygen atoms destabilizes the second TS and leads to decreased catalytic effi-ciency in ester hydrolysis TyrB444 at the active site

of GGT (Protein Data Bank ID: 2dbx [22]) can inter-act with the leaving group similarly to the main chain carbonyl group of GlnB23 in PGA However, this Tyr residue can be both a donor and an acceptor of

a hydrogen bond Such an interaction cannot be real-ized at the active site of AGA, because no proper functional group could be found within a 4 A˚ radius from the leaving group heteroatom (Protein Data Bank ID: 1apz [23])

GlnB23 plays critical role in the process of deacyla-tion The acyl acceptor (a water molecule) forms a hydrogen bond with the main chain carbonyl oxygen

of GlnB23 [12] This bond is present in the intermedi-ate formed after the nucleophilic attack of the wintermedi-ater molecule Its deprotonation by the a-amino group of SerB1 is favored by stronger interaction of the general base with the side chain oxygens of AsnB241 and

Scheme 2 Modified scheme of the

cata-lytic mechanism of the PGA-catalyzed

hydrolytic reaction.

GlnB23 (the basicity of aN of SerB1 is increased).

Thus TIdeac. is formed, in which the oxyanion is

stabi-lized by the oxyanion hole residues and additionally by

the protonated a-amino group of SerB1 During the

breakdown of TIdeacyl., the increasing negative charge

of the leaving OcSerB1 is balanced by the main chain

NH of GlnB23

On the basis of the presented kinetic results and the

QM model, we propose a modified scheme of the

cata-lytic mechanism of PGA, in which some of the

intra-molecular interactions essential for catalysis are

included (Scheme 2)

Conclusion

We present an experimental Hammett plot for the

PGA-catalyzed hydrolysis of a series of phenylacetyl

p-substituted anilides The proposed interpretation of

its complex character is based on an extended QM

model, in which specific ES interactions are taken

into account Several functional groups in the vicinity

of the catalytic center are assigned functions in

catal-ysis The a-amino group of SerB1 and the main chain

NH of GlnB23 activate and stabilize the c-hydroxyl

group of SerB1 for nucleophilic attack on the

sub-strate The protonated general base interacts with the

side chain carbonyl oxygens of GlnB23 and AsnB241,

and contributes to the stabilization of the oxyanion

in the TI The main chain carbonyl group of GlnB23

forms a hydrogen bond with the leaving group

nitro-gen, thus influencing the hydrolysis rate The specific

orientation and interaction of several amino acids at

the active site of PGA, combined with the effect of

the substituent on the geometry of the second TS,

leads to a change in the reaction pathway and the

rate-limiting step for the strong electron-withdrawing

substituents

Experimental procedures

Organic solvents and initial arylamines were purchased

from Fluka (Darmstadt, Germany) and used without

further purification PGA was purchased from Sigma

(St Louis, MO, USA)

PGA active site titration

Aliquots of the enzyme solution were incubated for a set

time with varying amounts of phenylmethanesulfonyl

fluo-ride (irreversible inhibitor of serine proteases) in 50 mm

sodium phosphate buffer (pH 7.0) An aliquot of every

sample was then used to catalyze the hydrolysis of a

constant amount of the chromogenic substrate

2-nitro-5-phenylacetamidobenzoic acid at 25C in 50 mm sodium phosphate buffer (pH 7.0) containing 10% dimethylsulfox-ide (v⁄ v) The release of 5-amino-2-nitrobenzoic acid allows the progress of the reaction to be followed spectro-photometrically (k = 380 nm) The decrease of PGA activity as a function of the amount of the inhibitor was used to calculate the molar concentration of the enzyme [24]

Synthesis of substrates for PGA

N-(4-methoxyphenyl)-2-phenylacetamide, N-(4-methylphenyl)-2-phenylacetamide, ethyl 4-[(phenylacetyl)amino]benzoate, N-(4-acetylphenyl)-2-phenylacetamide, N-(4-cyanophenyl)-2-phenylacetamide and N-(4-nitrophenyl)-2-N-(4-cyanophenyl)-2-phenylacetamide were obtained by the following procedure One equivalent

of the p-substituted aniline and 1.1 equivalent amino base (NEt3, N-methylmorpholine) were mixed in organic solvent (tetrahydrofuran, chloroform) at 0C, and 1.2 equivalents

of phenylacetyl chloride were added dropwise The mixture was stirred at room temperature for 1–5 h At the end of the reaction, the hydrochloride of the organic base was fil-tered When chloroform was used, the reaction mixture was washed consecutively with 0.1 m HCl, a saturated solution

of NaHCO3, and distilled water, and dried over MgSO4 The organic solvent was evaporated, and the residue was crystallized from ethanol, except for N-(4-cyanophenyl)-2-phenylacetamide, which was crystallized from water, and N-(4-nitrophenyl)-2-phenylacetamide, which was crystallized from benzene N,2-diphenylacetamide, N-(4-bromophenyl)-2-phenylacetamide and 2-phenyl-N-[4-(trifluoromethyl)-phenyl]acetamide were obtained by Schotten–Baumann acylation: one equivalent of the p-substituted aniline was dissolved in 10% aqueous NaOH; ethanol was added to increase the solubility of the reagent The mixture was cooled to 0C, and 1.2 equivalents of phenylacetyl chloride were added The reaction mixture was stirred at room tem-perature for 1–5 h The precipitate was filtered, washed with cold distilled water, and crystallized from EtOH (N,2-diphenylacetamide was crystallized from methanol⁄ water) The purity of the synthesized substrates was confirmed

by means of elemental analysis, 1H-NMR spectroscopy (Bruker Avance DRX 250), and melting point determina-tion (Bu¨chi B-540) The results were in good agreement with those reported in the literature [15,25,26] 2-Phenyl-N-[4-(trifluoromethyl)-phenyl]acetamide (melting point 161–

162C) was newly synthesized The results of the elemental analysis were as follows for C15H12NOF3: calculated (%),

C – 64.51, H – 4.33, and N – 5.02; found (%), C – 64.61,

H – 4.38, and N – 4.97 Chemical shifts in the

1H-NMR spectrum were as follows: dH, p.p.m relative to tetramethylsilane (dimethylsulfoxide-D6), 3.69 (2H, s,

C6H4CH2CO), 7.34–7.22 (5H, m, C6H4CH2CO), 7.66 (2H,

d, J = 8.5 Hz, NHC6H4CF3), 7.81 (2H, d, J = 8.5 Hz, NHC6H4CF3), and 10.54 (1H, s, CONH)

PGA-catalyzed hydrolysis of the phenylacetyl

p-substituted anilides

Reactions were performed at 25C in 0.1 m sodium

phos-phate buffer (pH 7.0) containing 10% dimethylsulfoxide

(v⁄ v) The total volume of the reaction mixture was

2000 lL The initial substrate concentration ranged

from about 0.2 to 4.0 Km, with the exception of

N-(4-cyanophenyl)-2-phenylacetamide,

N-(4-bromophenyl)-2-phenylacetamide, and

2-phenyl-N-[4-(trifluoromethyl)-phenyl]acetamide, in which cases the interval was narrower,

owing to limited solubility of the substrates in the reaction

mixture The enzyme concentration was about three orders

of magnitude lower The reaction was followed using a

Shimadzu UV-3000 UV–visible spectrophotometer at a

wavelength with maximum difference between substrate

and product molar absorption coefficients, as follows

[R (PhCH2CONHC6H4-pR) – kdetection (nm)]: NO2 – 416;

CN – 303; COCH3 – 340; COOC2H5 – 317; CF3 – 260;

Br – 266; H – 260; CH3– 265; and OCH3 – 265

Calibra-tion curves for both the substrate and the free aniline were

prepared, and initial velocities were calculated, taking into

account both the consumption of the substrate and the

lib-eration of the arylamine with the time The kinetic

experi-ments with each substrate concentration were performed in

triplicate The turnover number and the Michaelis constant

were determined by nonlinear regression analysis

Computational methods

The covalent complex of PGA with the irreversible

inhibi-tor phenylmethanesulfonyl fluoride was taken as an initial

structure (Protein Data Bank ID: 1pnm from the Research

Collaboratory for Structural Bioinformatics Protein Data

Bank, http://www.pdb.org) It was modified by the

follow-ing procedure, usfollow-ing the ds viewerpro 6.0 software

pack-age (Accelrys Software Inc., San Diego, CA, USA) (now

Discovery Studio:

http://accelrys.com/products/discovery-studio/) The sulfur in the SO2group was replaced with a

carbon atom One of the two oxygen atoms was

trans-formed into O), and the other into nitrogen; thus, the two

double S = O bonds were replaced by C–O) and C–N

bonds The leaving group – a phenyl residue – was then

added to the nitrogen atom The resultant structure was the

TI of the hydrolysis of phenylacetyl anilide (R = H) This

enzymatic complex was then optimized by MM calculations

with the Drieding force field, using ds viewer [27] All

atoms belonging to the protein moiety were fixed during

the optimization, except for SerB1 covalently bound to the

TI

The model of the active center of PGA was then

con-structed using the optimized positions of the atoms of

SerB1, AlaB69, AsnB241, GlnB23 and the TI after

substitu-tion of the phenyl ring in the acyl moiety of the substrate

with a hydrogen atom The spatial structure of the model

TI of acetanilide was optimized by AM1 QM computations with the gaussian 98 software package [28]

Based on the structure of TI for acetanilide, the two TSs

of the nucleophilic attack of the side chain of SerB1 and the collapse of TI were modeled The stable structures and the TSs were fully optimized at the AM1 level of theory [28] All stationary points were further characterized by analytic computations of harmonic vibrational frequencies TSs were located using the synchronous transit-guided quasi-Newton methods, implemented in gaussian [29] Transition structures were checked by intrinsic reaction coordinate calculations [30]

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Supporting information

The following supplementary material is available: Fig S1 Putative binding of phenylacetyl p-nitroanilide

at the active site of penicillin G acylase

Fig S2 Brønsted plots for the hydrolysis of a series

of phenylacetyl p-substituted anilides catalyzed by penicillin G acylase from E coli

Fig S3 Michaelis complex of phenylacetanilide with penicillin G acylase optimized by molecular mechanics with the Dreiding force field

Fig S4 Structure of the Michaelis complex of penicil-lin G with penicilpenicil-lin G acylase optimized by MM cal-culations with the Dreiding force field

This supplementary material can be found in the online version of this article

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