Báo cáo khóa học: Active site residues and mechanism of UDP-glucose dehydrogenase ppt

Studies with a mutant of the key active site nucleophile, Cys260Ala, show that it is capable of both reducing the aldehyde intermediate, and oxidizing the hydrated form of the aldehyde i

Active site residues and mechanism of UDP-glucose dehydrogenase

Xue Ge1, Lisa C Penney1, Ivo van de Rijn2and Martin E Tanner1

1 Department of Chemistry, University of British Columbia, Vancouver, Canada; 2 Wake Forest University School of Medicine, Winston-Salem, NC, USA

UDP-glucose dehydrogenase catalyzes the NAD+

-depend-ent twofold oxidation of UDP-glucose to give

UDP-glucu-ronic acid A sequestered aldehyde intermediate is produced

in the first oxidation step and a covalently bound thioester is

produced in the second oxidation step This work

demon-strates that the Streptococcus pyogenes enzyme incorporates

a single solvent-derived oxygen atom during catalysis and

probably does not generate an imine intermediate The

reaction of UDP-[6¢¢,6¢¢-di-2H]-D-glucose is not

accompan-ied by a primary kinetic isotope effect, indicating that

hydride transfer is not rate determining in this reaction

Studies with a mutant of the key active site nucleophile,

Cys260Ala, show that it is capable of both reducing the

aldehyde intermediate, and oxidizing the hydrated form of

the aldehyde intermediate but is incapable of oxidizing

UDP-glucose to UDP-glucuronic acid In the latter case, a ternary Cys260Ala/aldehyde intermediate/NADH complex is pre-sumably formed, but it does not proceed to product as both release and hydration of the bound aldehyde occur slowly A washout experiment demonstrates that the NADH in this ternary complex is not exchangeable with external NADH, indicating that dissociation only occurs after the addition of a nucleophile to the aldehyde carbonyl Studies on Thr118Ala show that the value of kcat is reduced 160-fold by this mutation, and that the reaction of UDP-D-[6¢¢,6¢¢-di-2 H]-glucose is now accompanied by a primary kinetic isotope effect This indicates that the barriers for the hydride transfer steps have been selectively increased and supports a mech-anism in which an ordered water molecule (H-bonded to Thr118) serves as the catalytic base in these steps

UDP-glucose dehydrogenase catalyzes an NAD+

-depend-ent twofold oxidation of glucose to generate

UDP-glucuronic acid (Fig 1) [1] In mammals, UDP-UDP-glucuronic

acid is used in the biosynthesis of hyaluronan and various

glycosaminoglycans such as heparin sulfate and chondroitin

sulfate [2] In addition, it is used in the liver where the act of

glucuronidation targets molecules for excretion [3]

UDP-glucuronic acid also serves as a precursor to UDP-xylose

which provides a major component of the cell wall

polysac-charides in plants [4] In many strains of pathogenic bacteria,

such as group A streptoccoci and Streptococcus pneumoniae

type 3, UDP-glucuronic acid is used in the construction of

the antiphagocytic capsular polysaccharide [5,6] This

cap-sule protects the bacteria from the immune system of the

host and thus serves as a major virulence factor

UDP-glucose dehydrogenase is of mechanistic interest

because it belongs to a family of sugar nucleotide-modifying

enzymes that catalyze a net four-electron oxidation and

thus effectively serve as both alcohol dehydrogenases and

aldehyde dehydrogenases [7] Other members of this

family include UDP-ManNAc dehydrogenase [8] and

GDP-mannose dehydrogenase [9,10] Extensive studies on

both the bovine and S pyogenes UDP-glucose dehydro-genases have led to the mechanistic pathway outlined in Fig 1 The enzyme is thought to follow a Bi-Uni-Uni-Bi ping-pong mechanism in which UDP-glucose is bound first and UDP-glucuronic acid is released last [11,12] The first oxidation involves the transfer of the C-6¢ pro-R hydride

of UDP-glucose to the si face (B face) of NAD+to form NADH and an aldehyde intermediate [13,14] This inter-mediate is bound tightly to the enzyme and is not accessible

to external aldehyde-trapping reagents [15,16] Nevertheless,

it has been demonstrated that synthetic samples of the aldehyde intermediate will serve as a kinetically competent substrate for the second step of the reaction [17] It is quite likely that the bound form of the aldehyde exists largely as

a covalent hemithioacetal adduct as this species has been implicated as an intermediate in the second step of catalysis, although an imine linkage via an active site lysine has also been proposed [18] The second oxidation step involves the addition of a cysteine thiol to the aldehyde to generate the thiohemiacetal intermediate with subsequent hydride trans-fer to the second NAD+molecule [19,20] The resulting thioester is hydrolyzed in a final step to generate the product, UDP-glucuronic acid

Strong evidence in support of this covalent catalysis mechanism was obtained when a Cys260Ser mutant of the

S pyogenesenzyme was incubated with UDP-glucose and NAD+[20] The mutant enzyme was essentially inactive; however, mass spectral analysis indicated that a covalent adduct had accumulated in which UDP-glucuronic acid was attached to Ser260 via an ester linkage The mutant enzyme was therefore capable of catalyzing both oxidation steps of the reaction but was incapable of hydrolyzing the unnatural ester bond at any significant rate Interestingly, when the

Correspondence to M E Tanner, Department of Chemistry,

University of British Columbia, 2036 Main Mall, Vancouver,

British Columbia, Canada V6T 1Z1.

Tel.: +1 604 822 9453, Fax: +1 604 822 2847,

E-mail: mtanner@chem.ubc.ca

Abbreviations: GAPDH, glyceraldehyde phosphate dehydrogenase.

Enzyme: UDP-glucose dehydrogenase (EC 1.1.1.22).

(Received 29 August 2003, revised 9 October 2003,

accepted 14 October 2003)

Cys260Ala mutant was examined, the enzyme was

essen-tially inactive towards UDP-glucose oxidation but readily

oxidized the intermediate aldehyde at a rate within an order

of magnitude of that seen with the wild-type enzyme

Apparently, the normal reaction proceeds via covalent

catalysis; however, with the alanine mutant the second

oxidation step can proceed directly from the hydrated

aldehyde (Fig 2)

In subsequent work, X-ray structures were solved of the

native and Cys260Ser dehydrogenases from S pyogenes

in complex with UDP-xylose/NAD+and UDP-glucuronic

acid/NAD(H), respectively [21] In each case, Cys/Ser260

was positioned appropriately to participate in covalent

catalysis, as expected Other active site residues that could

potentially play roles in the hydride transfer and/or

hydro-lysis steps were also identified These include Thr118,

Glu141, Glu145, Lys204, Asn208, and Asp264 All but

Glu145 are strictly conserved among all family members

Inspection of the hydrogen bonding networks at the site that

would be occupied by the C-6¢ hydroxyl of UDP-glucose in

the Michaelis complex led to the proposal of two scenarios

for the hydride transfer steps (presumably both hydride

transfer steps will employ the same catalytic residues) In

the first scenario, Lys204 acts as the catalytic base that

deprotonates the C-6¢ hydroxyl, whereas Asn208 and an

ordered water molecule serve as hydrogen bond donors to

the hydroxyl oxygen (Fig 3A) In the second scenario, the

ordered water molecule serves as the catalytic base with the

assistance of Asp264 as the ultimate proton acceptor

(Fig 3B) In this case, Asn208 and Lys204 (presumably in

the ammonium form) serve as hydrogen bond donors to the

hydroxyl oxygen, and Thr118 and a ribose hydroxyl of

NAD+form hydrogen bonds with the ordered water The

identity of the catalytic residues involved in hydrolysis of

the thioester intermediate are harder to predict from these

structures; however, Glu141 and Glu145 are potential

candidates

In this work, the possibility of imine formation involving

Lys204 is examined with the use of H218O, and the nature

of the rate determining steps of catalysis is probed using

deuterated UDP-glucose Studies on the Cys260Ala

mutant and other active site mutants are described which

help to further delineate the roles these residues play in catalysis

Experimental procedures

General procedures UDP-glucose dehydrogenase from S pyogenes was expressed in Escherichia coli using the plasmid pGAC147

as described elsewhere [5] All proteins were purified as described previously [12] and analyzed by ESI-MS to ensure they had the expected molecular masses All enzymatic assays for dehydrogenase activity used the method des-cribed previously [12], unless otherwise indicated The aldehyde intermediate, uridine diphospho-a-D -gluco-hexodialdose, was synthesized as described previously [17], and stock concentrations were calculated from measure-ments of A262 using a value of e262¼ 8700M )1 for the uridine chromophore H218O (95% enriched) was from Cambridge Isotope Laboratories [6,6-di-2H]-D-Glucose (98% enriched) was from Aldrich Commercial enzymes and sugar nucleotides were from Sigma or Boehringer Mannheim Biochemicals, unless stated otherwise

Site-directed mutagenesis and mutant protein expression

The mutagenesis protocol to produce the active site mutants followed an adaptation of enzymatic PCR [22] using plasmid pGAC147 [5] which contains a copy of hasB as template The primers for the construction of the mutant plasmids were as follows: T118A, 5¢-CGCGGTACCAAC TCTTATCATCAAATCAGCAATTC-3¢ and 5¢-ATAG GTACCATGGCTATTAACGCTTAGTACC-3¢; E141Q, 5¢-CGCGGTACCTTTATATGACAACTTATATC-3¢ and 5¢-ATAGGTACCTTTAGATTCTCTTAAAAACTG AGGGC-3¢; E145Q, 5¢-CGCGGTACCTTTATATGAC AACTTATATC-3¢ and 5¢-ATAGGTACCTTTAGACTG TCTTAAAAATTCAG-3¢; K204A, 5¢-CGCGGTACCC AATACTTATTTAGCG-3¢ and 5¢-ATAGGTACCAAA TAGTGCTACTGCTTCAGC-3¢; N208A, 5¢-CGCGGTA CCGTTAAGGGTAGC-3¢ and 5¢-ATAGGTACCTAAA

Fig 1 The mechanism of the reaction

cata-lyzed by UDP-glucose dehydrogenase.

TAAGTAGCGGCAAATAG-3¢; D264N, 5¢-CGCGGTA

CCCAATTATTGGCAAATTAC-3¢ and 5¢-ATAGGTAC

CTTCGTGTTTTTAGGTAGACA-ATAAC-3¢

Nucleo-tides designated in bold led to the desired mutations

Cys260Ala was expressed using the plasmid pGAC400 as

described previously [20] All mutations and constructs were

confirmed by sequencing the entire gene

Expression experiments of the mutant constructs

were initiated by transforming each plasmid into E coli

JM109(DE3) and colonies were grown overnight in TYPG

(3 mL) The TYPG media contained 8 g of tryptone, 8 g

of yeast extract, 2.5 g of NaCl, 1.25 g of K2HPO4 and

2.5 g of glucose per 500 mL of distilled water For

inductions, either the JM109(DE3) culture harboring

pGAC147 (3 mL) or the JM109(DE3) culture harboring

the desired mutant construct (0.5 mL) was inoculated into

TYPG (250 mL) and grown at 37C with vigorous

shaking until the cultures reached D600 ¼ 0.8–1.2 An

aliquot of the culture (10 mL) was removed just prior to

induction by isopropyl thio-b-D-galactoside (0.4 mM final

concentration) and the incubation was resumed Following

induction aliquots of culture (10 mL) were removed at 1-h

intervals, rapidly chilled on ice, and a portion (1.5 mL)

was prepared for SDS/PAGE analysis Bacteria were

sedimented at 13 000 g (10 s), the pellets were resuspended

in TE (150 lL; 10 mM Tris pH 7.5, 1 mM EDTA), and

finally the cells were solubilized by boiling for 5 min in the

presence of 6· loading buffer (30 lL [23]) SDS/PAGE

was performed by the method of Laemmli [24] using 10%

gels and loading 20 lL lysate per lane to confirm the

overexpression of the mutant constructs

Solvent isotope incorporation study

A solution of sodium phosphate buffer (50 mM, 500 lL),

pH 8.0, containing 50% H218O (v/v), UDP-glucose

(50 mM), NAD+ (10 mM), FMN (10 mM), dithiothreitol

(2 mM), and UDP-glucose dehydrogenase (0.35 mg) was

incubated at 37C for 20 h At periodic intervals the

reaction was gently mixed and exposed to atmospheric

oxygen After the incubation, EDTA (16 mM) was added

and the mixture was lyophilized to dryness The residue was

redissolved in D2O and13C NMR spectra were recorded A

control sample was run containing 100% H216O

For further purification, the samples were applied to a

column of Bio-Gel P-2 resin (40 mL) and eluted with

water Fractions containing the UDP-glucuronic acid

product were lyophilized and submitted for MALDI MS analysis

Kinetic isotope effect studies UDP-[6¢¢,6¢¢-di-2H]-D-glucose was prepared using a slight modification of a procedure previously described for the preparation of tritiated UDP-glucose [25] A solution

of Tris/HCl buffer (70 mM, 40 mL) pH 7.8, containing [6,6-di-2H]-D-glucose (8 mg, 44 lmol, 1.1 mM), ATP (73 mg, 132 lmol), UTP (64 mg, 132 lmol), glucose 1,6-diphosphate (0.165 lmol), MgSO4(36 mg, 146 lmol), hexokinase (66 U), phosphoglucomutase (109 U), UDP-glucose pyrophosphorylase (12.5 U), and inorganic pyro-phosphatase (33 U) was incubated at 30C for 20 h The reaction mixture was applied to a column of DE-52 anion exchange resin (65 mL) and eluted with a linear gradient of 0–400 mM triethylammonium bicarbonate (800 mL total) Fractions containing glucose (as assayed by UDP-glucose dehydrogenase and NAD+) were pooled, lyophi-lized, redissolved in water, and lyophilized a second time The product was redissolved in water and passed through a column of Amberlite IR-120 (plus) resin (10 mL, Na+ form, eluted with water) The resulting solution was applied

to a column of Bio-Gel P-2 resin (2.5· 45 cm) and eluted with water UV active fractions were pooled and lyophilized

to dryness to give the disodium salt of UDP-[6¢¢,6¢¢-di-2

H]-D-glucose as a white solid (29 lmol, 66% yield assayed enzymatically, see below).1H NMR and mass spectra were consistent with the assignment of the product as UDP-[6¢¢,6¢¢-di-2H]-D-glucose, and indicated the extent of deuter-ium incorporation to be > 95%; LSI(–) MS (thioglycerol) m/z 567 (M(di-2H)–H+, 100%)

The rates of the dehydrogenase reaction were determined under saturating conditions for both substrates using a previously described kinetic assay [12] The values of [UDP-glucose] (deuterated or undeuterated) and [NAD+] were

as follows: Wild-type enzyme (0.5 mM, 1.2 mM), T118A (0.5 mM, 4 mM), E141Q (0.5 mM, 2 mM), and E145Q (0.8 mM, 2 mM) The error reported for the kinetic isotope effects are the SD of the data points from the average determined ratios (five independent measurements) The concentrations of the stock UDP-glucose solu-tions (both deuterated and undeuterated) were determined

Fig 3 Two scenarios outlining the residues involved in catalyzing the hydride transfer steps (A) Lys204 serving as the key acid/base residue (B) An ordered water molecule and Asp264 serving as the key acid/ base residue X ¼ H for the first oxidation step, X ¼ SR (from Cys260) for the second oxidation step.

Fig 2 The proposed mechanism for the oxidation of the hydrated

aldehyde intermediate by the Cys260Ala mutant.

enzymatically by running the UDP-glucose dehydrogenase

reaction to completion The substrate concentrations were

calculated from the changes in A340 assuming a

stoichio-metry of two equivalents of NADH produced for every

molecule of UDP-glucose consumed, and an extinction

coefficient for NADH of e¼ 6220M )1

Cys260Ala studies

Initial velocity kinetics for the reduction of the aldehyde

intermediate Assays were performed at 30C in Trien/

HCl buffer (50 mM, 0.50 mL total volume) pH 8.7,

con-taining NADH (0.15 mM) and dithiothreitol (2 mM) with

varying amounts of aldehyde Initial velocities were

meas-ured during the first 60 s after initiation with the Cys260Ala

mutant and calculated from the decrease in A340using an

extinction coefficient for NADH of e¼ 6220M )1

Full time course analysis of incubations with the aldehyde

intermediate and NADH The aldehyde intermediate

(75 lM with wild-type enzyme, 92 lM with Cys260Ala)

was incubated at 30C with NADH (0.15 mM) and either

wild-type dehydrogenase (0.22 lM) or the Cys260Ala

mutant (0.22 lM) in Trien/HCl buffer (50 mM, 0.50 mL

total volume), pH 8.7, containing dithiothreitol (2 mM)

The changes in NADH concentrations were monitored

using A340assuming an extinction coefficient for NADH of

e¼ 6220M )1 To confirm the identity of the products at the

end-point of these reactions, aliquots were analyzed by

ion-paired reversed phase HPLC as described previously and

compared with authentic standards [14]

Deuterium washout experiment.A solution of Trien/HCl

buffer (50 mM, 2 mL total volume) pH 8.7, containing

UDP-D-[6¢,6¢-di-2H]-glucose (2 mM), NADH (20 mM),

NAD+(4 mM), dithiothreitol (2 mM), and the Cys260Ala

mutant (0.1 mg) was incubated at 30C for 23 h The

resulting solution was applied to a column of DE-52 anion

exchange resin (60 mL) and eluted with a linear gradient of

0–300 mM ammonium bicarbonate (800 mL total)

Frac-tions containing UDP-glucose (as assayed by UDP-glucose

dehydrogenase and NAD+) were pooled and lyophilized

The resulting solids were dissolved in water and passed

through a column of Amberlite IR-120 (plus) resin (10 mL,

Na+form, eluted with water) The eluent was lyophilized to

dryness, redissolved in water, applied to a column of

Bio-Gel P-2 resin (2.5· 45 cm), and eluted with water UV

active fractions were pooled and lyophilized to dryness The

UDP-D-[6¢¢,6¢¢-di-2H]-glucose obtained in this fashion was

analyzed for deuterium content by1H NMR spectroscopy

and LSI-MS, and showed identical spectral characteristics

to the original labeled material

Results

Solvent18O-isotope incorporation study

The fact that the aldehyde intermediate in the UDP-glucose

dehydrogenase reaction is never released into solution and is

inaccessible to external trapping reagents led to the

sugges-tion that this species is covalently bound to an active site

lysine residue via an imine linkage [18] This suggestion was

supported by experiments on the bovine liver enzyme in which the active site cysteine thiol had been chemically modified to a thiocyanide moiety When this inactivated form of the enzyme was incubated with UDP-glucose and NAD+(or with the aldehyde intermediate alone) and then treated with NaBH4, a covalent enzyme-substrate adduct was generated The properties of the adduct were consistent with that expected for a reduction product of a Schiff’s base formed between the aldehyde intermediate and an active site lysine, and the authors concluded that an imine was formed

on the normal reaction pathway The suggestion was somewhat at odds with earlier18O-isotopic labeling studies showing that the reaction proceeds with the incorporation

of only one solvent-derived oxygen atom into the carboxy-late product [26] The proposal of an imine intermediate could only be consistent with this observation if the original C6¢¢ oxygen atom was sequestered in the active site during the second oxidation step and then re-delivered during hydrolysis of the thioester

More recent work has focused on the bacterial enzyme from S pyogenes, and the X-ray crystal structure has shown that Lys204 is in the active site and is in close proximity

to C6¢ of UDP-glucose [21] In order to re-examine the possibility of Schiff base formation with this enzyme, the reaction was carried out in H218O water and the UDP-glucuronic acid produced was examined for 18O-isotope content Samples of UDP-glucose were incubated with substoichiometric amounts of NAD+ in the presence of FMN and oxygen [27,28] The FMN/O2acts as an NAD+ regenerating system and facilitates purification of the UDP-glucuronic acid from the minor dinucleotide contaminants Reactions were carried out in both H216O and 50%

H216O/50% H218O, and the resulting UDP-glucuronic acid was analyzed by MALDI TOF MS In the latter case, signals corresponding to both unlabeled (m/z 648.3, M-2H++3Na+) and singly 18O-labeled product (m/z 650.3) were observed in approximately equal amounts, confirming that the reaction was accompanied by incor-poration of a single solvent-derived oxygen atom In order

to determine the position of the incorporated 18O-atom, both samples were analyzed by13C NMR spectroscopy In the control sample, a single carboxylate signal is observed at 176.671 p.p.m., whereas, in the 50% H216O/50% H218O sample two signals of approximately equal intensity were observed at 176.673 and 176.647 p.p.m (Fig 4) The 0.026 p.p.m separation of the signals in the latter sample

is consistent with the magnitude expected for an18O-isotope induced shift in a mono-labeled carboxylate, and confirms that the label was introduced into the carboxylate of UDP-glucuronic acid [28]

Deuterium kinetic isotope effect study

In order to determine if either hydride transfer step in the reaction catalyzed by UDP-glucose dehydrogenase was rate determining, samples of 6¢¢,6¢¢-dideuterated-UDP-glucose were prepared and analyzed for the pres-ence of a primary kinetic isotope effect on catalysis Since both C6¢¢ positions were labeled, a single experi-ment could be used to simultaneously probe both hydride transfer steps UDP-[6¢¢,6¢¢-di-2H]-D-glucose was prepared enzymatically from [6,6-di-2H]- -glucose using

hexokinase, phosphoglucomutase, UDP-glucose

pyro-phosphorylase, and inorganic pyrophosphatase The

resulting UDP-[6¢¢,6¢¢-di-2H]-D-glucose was found to be

> 95% enriched with two deuterium labels when

ana-lyzed by MS The rates of the UDP-glucose

dehydro-genase reaction for both the labeled and unlabeled

substrates were determined under saturating conditions

and the value of kH/kDwas found to be 1.1 ± 0.1 This

demonstrates that there is no primary kinetic isotope

effect on the reaction of this substrate and therefore the

hydride transfer steps are not rate determining in this

reaction

Site-directed mutagenesis

In an effort to further understand the roles of the active site

residues in catalysis several mutant proteins were targeted

for study Plasmids encoding Thr118Ala, Glu141Gln,

Glu145Gln, Lys204Ala, Asn208Ala, Cys260Ala, and

Asp264Asn were generated and shown to result in high

levels of protein expression Unfortunately, with several of

the key mutants (K204A, N208A, and D264N), all of the

expressed protein was produced in insoluble inclusion

bodies and attempts to solubilize these proteins were

unsuccessful With Cys260Ala, much of the protein was

present in inclusion bodies, however, enough remained in

solution to allow for the purification and study of this

mutant Thr118Ala, Glu141Gln, and Glu145Gln were

soluble and could be isolated in good yield

Studies on Cys260Ala

Cys260 provides the key active site thiol involved in covalent

catalysis with this enzyme and thus mutants of this residue

warrant further investigation In previous studies, the Cys260Ala mutant was reported to be essentially inactive towards the oxidation of UDP-glucose (< 0.01% activity

of wild-type enzyme) [20] However, the mutant was quite capable of catalyzing the oxidation of the aldehyde inter-mediate at rates within an order of magnitude of that of the wild-type enzyme (kcat¼ 0.19 s)1, KM¼ 0.26 mM vs

kcat¼ 1.2 s)1, KM¼ 0.014 mM, respectively) Since this mutant is presumably incapable of participating in covalent catalysis, it would appear that it simply binds the hydrated form of the aldehyde from solution and oxidizes it directly

to UDP-glucuronic acid (Fig 2) The question remains, however, as to why UDP-glucose is not a substrate for the Cys260Ala mutant One possibility is that the Cys260 thiol plays a key role in the first oxidation step of the reaction, in addition to its role in covalent catalysis during the second oxidation step An alternate possibility is that Cys260 is not required for the first oxidation step and the aldehyde intermediate is readily formed by the mutant enzyme; however, it is tightly bound and there is no mechanism by which it can be hydrated and proceed forward to the second oxidation step

In order to address the previous question, the ability of the Cys260Ala mutant to catalyze the reverse of the first step

in catalysis, namely reduction of the aldehyde intermediate, was examined The aldehyde intermediate was generated via chemical synthesis and was found to be an excellent substrate for reduction by NADH using the Cys260Ala mutant The values of kcatand KMfor the aldehyde were determined (at 0.15 mMNADH) to be 1.9 ± 0.1 s)1and

58 ± 7 lM, respectively (it was not possible to measure these values with the wild-type enzyme due to a dismutation process, vide infra) It should be noted that the value of KM essentially represents an Ôapparent KMÕ since the majority of the aldehyde in solution exists as a hydrate [17] and the reduction process requires that the enzyme bind the unhydrated form of the aldehyde The observation that Cys260Ala catalyzes a reasonably rapid reduction of the aldehyde clearly demonstrates that Cys260 does not play a key role in catalysis of the first oxidation step It also means that Cys260Ala must be capable of catalyzing the reverse reaction, namely the oxidation of UDP-glucose to give the free aldehyde The Haldane equation dictates that the extremely slow rate of this oxidation process must ulti-mately be attributed to an unfavorable equilibrium constant reflecting the higher energies of the free aldehyde and NADH

These observations are further supported by monitoring the full time course of the reaction of the aldehyde intermediate with excess NADH (Fig 5) When the wild-type enzyme is the catalyst, an initial decrease in A340 is observed due to the reduction of the aldehyde that generates NAD+and UDP-glucose As NAD+accumulates, how-ever, it is possible for the enzyme to oxidize either the aldehyde intermediate or UDP-glucose to UDP-glucuronic acid and regenerate NADH Ultimately, the A340 value returns to its initial position, indicating there is no net consumption of NADH This phenomenon can be under-stood by considering a dismutation process in which the aldehyde disproportionates between the alcohol and the acid without consuming NADH (Fig 6) The thermodynamic stability of UDP-glucuronic acid ultimately drives the

Fig 4.13C NMR spectra of the carboxyl group of UDP-glucuronic acid

(A) generated in 50% H 218O/50% H 216O and (B) generated in

100% H 16

2 O.

dismutation to completion With the Cys260Ala mutant, a

rapid decrease in A340is observed due to reduction of the

aldehyde intermediate and the consumption of NADH

(Fig 5) In this case, however, the NADH is not regenerated

by the dismutation process and the value of A340does not

return to its original position This occurs because the

UDP-glucose that is generated by reduction of the aldehyde

cannot be oxidized by this mutant and is therefore kinetically

trapped in that form By calculating the amount of NAD+

consumed, it was found that 80% of the aldehyde was

converted to UDP-glucose in this fashion The remaining 20% of the aldehyde did undergo dismutation since a fraction of it was oxidized directly to the acid by the enzyme and the accumulating NAD+ In both experiments, HPLC analysis with authentic standards of the UDP-sugars was used to confirm the expected product distributions This kinetic behavior is entirely consistent with the curious observation that Cys260Ala can both oxidize the aldehyde

to the acid and reduce it to the alcohol, but that it cannot oxidize the alcohol to the acid at any appreciable rate Since the Cys260Ala mutant is capable of catalyzing the first hydride transfer step, the ternary complex of bound NADH and aldehyde intermediate must be formed upon incubation of the alcohol and NAD+ In order to proceed with the second oxidation step, however, a nucleophile must add to the aldehyde, and in the absence of the active site thiol a water molecule must assume this role If neither release, nor hydration, of the bound aldehyde can proceed

at a reasonable rate, no turnover would be observed and the only fate of the bound species would be to return to starting materials via the reverse reaction In order to probe further the nature of this ternary complex an experiment was devised to determine whether the bound NADH could exchange into bulk solution at any measurable rate A sample of UDP-D-[6¢¢,6¢¢-di-2H]-glucose was incubated with the Cys260Ala mutant in the presence of 20 mM NADH and 4 mM NAD+ An initial oxidation event should produce a ternary complex of the monodeuterated aldehyde and NAD2H If the bound NAD2H could exchange with unlabeled NADH, then back reaction would lead to the formation of monodeuterated UDP-glucose, and a net ÔwashoutÕ of the pro-R deuterium should be observed Even upon extensive incubations, however, no significant loss of deuterium label could be detected in the recovered UDP-D -[6¢¢,6¢¢-di-2H]-glucose as analyzed by both MS and1H NMR spectroscopy This indicates that the NADH is not released into solution from the mutant ternary complex and suggests that in the wild-type reaction, the first-formed NADH is not released until the Cys260 thiolate adds to bound aldehyde and generates the thiohemiacetal intermediate

Studies on Thr118Ala, Glu141Gln, and Glu145Gln The three remaining mutants that could be obtained in a soluble form were analyzed for their ability to catalyze the UDP-glucose dehydrogenase reaction (Table 1) E141Q and E145Q showed similar behavior in that the values for

Fig 6 The dismutation of the aldehyde intermediate during an

incuba-tion with NADH and wild-type UDP-glucose dehydrogenase Boxed

structures represent species present at the completion of the reaction.

Fig 5 Kinetic trace following the full time-course of the incubation of

the aldehyde intermediate and NADH with either wild-type

UDP-glucose dehydrogenase (solid line) or the Cys260Ala mutant (dashed

line).

Table 1 Kinetic constants and kinetic isotope effects for the reactions catalyzed by the wild-type and mutant UDP-glucose dehydrogenases.

Enzyme

UDP-Glc

K M (l M )

NAD+

K M (l M ) k cat (s)1) k H /k Da

Wild-type 20 ± 4 65 ± 6 1.8 ± 0.1 1.1 ± 0.1 T118A 59 ± 9 400 ± 100 0.011 ± 0.003 1.9 ± 0.1 E141Q 60 ± 9 135 ± 7 0.14 ± 0.02 1.4 ± 0.1 E145Q 125 ± 24 187 ± 20 0.20 ± 0.04 1.4 ± 0.1

a

Rate of UDP-glucose oxidation vs the rate of UDP-[6¢¢,6¢¢-di- 2 H]glucose oxidation measured under saturating conditions (see Experimental procedures).

kcatwere 10-fold lower than those obtained with the

wild-type dehydrogenase, and the values for KMwere two- to

six-fold higher The modest changes in the catalytic constants

suggest these active site residues do not play key roles in

either catalysis or binding In the case of Thr118Ala, the

value of kcatdropped by 160-fold, whereas the KMvalues

increased slightly This indicates that Thr118 is reasonably

important for catalysis, although it is probably not serving

as a key acid/base catalyst or nucleophile In order to probe

the nature of the steps that were affected by the mutations,

the mutants were examined for the possible presence of a

primary kinetic isotope effect on the oxdiation of

UDP-[6¢¢,6¢¢-di-2H]-D-glucose In the case of both E141Q and

E145Q, the kcatisotope effects were found to be 1.4 ± 0.1

In the case of Thr118Ala, however, kH/kDwas found to be

1.9 ± 0.1, consistent with the presence of a primary kinetic

isotope effect This indicates that with the Thr118Ala

mutant, one or both of the hydride transfer steps has

become the rate-limiting step of catalysis

Discussion

The isotope incorporation studies described in this

manu-script confirm that the S pyogenes UDP-glucose

dehydro-genase reaction proceeds with the incorporation of a single

solvent derived oxygen atom into the product carboxylate

This is consistent with previous results obtained using the

bovine liver enzyme [26] This observation does not disprove

the existence of an imine intermediate during catalysis, since

the original C6¢¢ oxygen atom from UDP-glucose could

conceivably be sequestered within the active site and

redelivered into the product carboxylate during the final

hydrolysis step Nevertheless, the absence of any di-labeled

product, combined with a lack of any chemical rationale as

to a how imine formation could facilitate catalysis, argues

against the formation of such an intermediate Instead, it is

likely that once the aldehyde is formed, the thiol of Cys260

readily adds to generate the covalently bound

thiohemi-acetal intermediate (Fig 1) In the previous studies that

used the thiocyanide-modified bovine enzyme and NaBH4

trapping, the isolated adduct was probably formed as a

result of the unnatural modification to the active site thiol

that prevents the aldehyde from proceeding forward in

catalysis [18] Thus, the imine formation observed with the

modified enzyme probably does not reflect a step that

occurs in the normal reaction pathway

The absence of any primary kinetic isotope effect during

the oxidation of UDP-D-[6¢¢,6¢¢-di-2H]-glucose indicates that

neither of the hydride transfer steps are rate determining in

the reaction of the wild-type enzyme Instead, another

chemical step such as the hydrolysis of the thioester

intermediate may be rate determining This was clearly the

case with the Cys260Ser mutant in which the ester

intermediate accumulated and could be isolated [20] Kinetic

studies have also led to the suggestion that an irreversible

thioester hydrolysis step is rate determining in the case of the

beef liver enzyme [11]

Studies with the Cys260Ala mutant showed that this

mutant is still capable of oxidizing the aldehyde

intermedi-ate at a reasonable rintermedi-ate [20] It is likely that the mutant is

binding the hydrated aldehyde from solution and oxidizing

it directly to the acid without using covalent catalysis

(Fig 2) Similar observations have been made with the phosphorylating glyceraldehyde 3-phosphate dehydro-genase (GAPDH) from E coli [29] This enzyme normally oxidizes an aldehyde using a thiol-based covalent catalysis strategy similar to the second step of the UDP-glucose dehydrogenase reaction The resulting thioester intermedi-ate is attacked by phosphintermedi-ate to generintermedi-ate the acyl phosphintermedi-ate product, 1,3-diphosphoglycerate When the active site cysteine was converted to an alanine, however, the resulting mutant catalyzed the formation of 3-phosphoglycerate as the sole product It was suggested that the mutant had oxidized the hydrated form of the aldehyde directly to the acid, and was thereby converted into a nonphosphorylating GAPDH Other enzymes, such as histidinol dehydrogenase [30,31] and alcohol dehydrogenase [32,33], are also known

to be able to oxidize hydrated aldehydes directly to acids without using covalent catalysis

The observation that the Cys260Ala mutant of UDP-glucose dehydrogenase can efficiently catalyze the reverse of the first oxidation step, namely reduction of the aldehyde intermediate, indicates that the Cys260 is not required for this step Instead, the inability of this mutant to catalyze the overall oxidation of the alcohol to the acid must be due to the reasonably high energy of the aldehyde intermediate In the reaction of the wild-type enzyme, this intermediate is stabilized by binding interactions with active site residues and is readily converted to the thiohemiacetal by attack of Cys260 In the case of Cys260Ala, however, the only way for catalysis to proceed is for the intermediate to be released into solution and then rebound as the hydrate Apparently release of the aldehyde intermediate is very slow, and hydration of the bound aldehyde does not readily occur, hence the overall rate of catalysis is also very slow This phenomenon is readily apparent when the full time course

of the aldehyde reduction is observed With the wild-type enzyme, an initial reduction of the aldehyde is observed, followed by oxidation of the aldehyde/alcohol as NAD+ accumulates The net result is a dismutation in which the aldehyde is converted into equimolar amounts of alcohol and acid, with no net consumption of NADH Similar dismutation processes have been observed with alcohol dehydrogenases that show aldehyde dehydrogenase activit-ies [32,33] In the case of Cys260Ala, however, the initial reduction phase generates a great deal of UDP-glucose that

is kinetically trapped and cannot be reoxidized at any appreciable rate Only 20% of the aldehyde underwent dismutation in this case The final experiment with Cys260Ala was a test for NADH exchange in the ternary dehydrogenase/aldehyde/NADH complex The absence of deuterium washout from UDP-[6¢¢,6¢¢-di-2H]-D-glucose dur-ing an incubation with the mutant, NAD+, and excess NADH shows that the NAD2H formed in the initial oxidation step does not exchange with free NADH Its only fate, therefore, is a back reaction to produce the initial starting materials A similar ternary complex is also formed

in the case of the wild-type reaction; however, the thiol group of Cys260 can readily add to the aldehyde carbonyl group The first formed NADH may then exchange with NAD+and the second oxidation step may proceed The results obtained with the mutant enzyme are consistent with the idea that cofactor exchange only takes place after the nucleophilic thiol adds to the carbonyl This helps to explain

how the enzyme efficiently sequesters the aldehyde

inter-mediate during catalysis

Our attempts at investigating the roles of other key active

site residues via mutagenesis studies were hampered by an

inability to isolate several of the mutants (Lys204Ala,

Asn208Ala, and Asp264Asn) in a soluble form Of the three

mutants that were amenable to purification (Thr118Ala,

Glu141Gln, and Glu145Gln), only Thr118Ala showed a

substantial reduction in catalytic efficiency This mutant

also showed a primary kinetic isotope effect upon the

oxidation of UDP-[6¢¢,6¢¢-di-2H]-D-glucose, indicating that a

hydride transfer step was rate limiting for catalysis

Con-sidering the two scenarios for residues involved in

promo-ting the hydride transfer steps [21], these observations are

most consistent with the one in which the ordered water

molecule serves as the catalytic base with the assistance of

Asp264 as the ultimate proton acceptor (Fig 3B) The

water molecule is within hydrogen bonding distance of

Thr118 and removing such an interaction would certainly

perturb its environment If the water molecule does play a

key role in the hydride transfer steps, then mutations to

Thr118 may increase the barrier to these steps and render

them rate determining Further investigations will be

necessary to fully outline the roles of the active site residues

in both the hydride transfer and thioester hydrolysis steps of

this interesting enzymatic transformation

Acknowledgements

This research was supported by NSERC (operating grant to M.E.T)

and the NIH (Public Health Service Grant AI37320 to I.v.d.R).

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