Báo cáo khoa học: Substrate specificity of the human UDP-glucuronosyltransferase UGT2B4 and UGT2B7 Identification of a critical aromatic amino acid residue at position 33 doc

Here, we show that in UGT2B4, sub-stitution of phenylalanine 33 by leucine suppressed the activity towards HDCA, and impaired the glucuronidation of several substrates, including 4-hydro

UDP-glucuronosyltransferase UGT2B4 and UGT2B7

Identification of a critical aromatic amino acid residue at

position 33

Lydia Barre1, Sylvie Fournel-Gigleux1, Moshe Finel2, Patrick Netter1, Jacques Magdalou1and Mohamed Ouzzine1

1 UMR 7561 CNRS, Universite´ Henri Poincare´ – Nancy I, Faculte´ de Me´decine, Vandoeuvre-le`s-Nancy, France

2 Drug Discovery and Development Technology Center (DDTC), Faculty of Pharmacy, University of Helsinki, Finland

UDP-glucuronosyltransferases (UGT) constitute a

super-family of enzymes that are involved in the phase II

detoxification pathway of many drugs, pollutants

pre-sent in our environment and numerous exogenous

compounds [1] They catalyze the formation of

glu-curonides by the transfer of glucuronic acid, from the

high energy donor UDP-glucuronic acid, to hydroxyl,

carboxyl or amine groups of structurally diverse

mole-cules The hydrophilic glucuronides are readily

excreted from the body via urine and bile Endogenous

compounds, such as bilirubin, fatty acids, steroids and

retinoic acid are also substrates of UGTs Thus, these

enzymes that are expressed in several tissues, such as

liver, lung, brain, kidney and gastro-intestinal tract,

play a major role in both physiological and toxicologi-cal processes [2]

UGTs have been classified into two main sub-families, UGT1A and UGT2B, based on similarities between their amino acid sequences and gene organiza-tion Molecular cloning of cDNAs has identified to date up to 16 human UGT isoforms, most of which have been extensively characterized in terms of sub-strate specificity upon heterologous expression [3] Determination of their activity towards series of sub-stances led to the conclusion that most of them present distinct, but frequently overlapping substrate specifici-ties [4] Interestingly, this redundancy provides an effi-cient protection against toxicity of drugs, pollutants

Keywords

site-directed mutagenesis; substrate

specificity; UDP-glucuronosyltransferase;

UGT2B4; UGT2B7

Correspondence

M Ouzzine, UMR 7561 CNRS-UHP-Nancy I,

Faculte´ de Me´decine, BP 184, F-54505

Vandoeuvre-le`s-Nancy cedex, France

Fax: +33 3 83683959

Tel: +33 3 83683972

E-mail: ouzzine@medecine.uhp-nancy.fr

(Received 10 November 2006, revised 21

December 2006, accepted 22 December

2006)

doi:10.1111/j.1742-4658.2007.05670.x

The human UDP-glucuronosyltransferase (UGT) isoforms UGT2B4 and UGT2B7 play a major role in the detoxification of bile acids, steroids and phenols These two isoforms present distinct but overlapping substrate spe-cificity, sharing common substrates such as the bile acid hyodeoxycholic acid (HDCA) and catechol-estrogens Here, we show that in UGT2B4, sub-stitution of phenylalanine 33 by leucine suppressed the activity towards HDCA, and impaired the glucuronidation of several substrates, including 4-hydroxyestrone and 17-epiestriol On the other hand, the substrate speci-ficity of the mutant UGT2B4F33Y, in which phenylalanine was replaced

by tyrosine, as found at position 33 of UGT2B7, was similar to wild-type UGT2B4 In the case of UGT2B7, replacement of tyrosine 33 by leucine strongly reduced the activity towards all the tested substrates, with the exception of 17-epiestriol In contrast, mutation of tyrosine 33 by phenyl-alanine exhibited similar or even somewhat higher activities than wild-type UGT2B7 Hence, the results strongly indicated that the presence of an aromatic residue at position 33 is important for the activity and substrate specificity of both UGT2B4 and UGT2B7

Abbreviations

HDCA, hyodeoxycholic acid; UGT, UDP-glucuronosyltransferase.

and harmful endogenous compounds When the

activ-ity of one isoform is impaired by mutations or upon

inhibition, other UGTs can often act as a relay to

overcome the deficiency Such redundancy in substrate

specificity is clearly observed for the human UGT2B4

and UGT2B7

UGT2B4 is mainly involved in the glucuronidation

of the bile acid, hyodeoxycholic acid (HDCA) [5] and

catechol-estrogens, such as 17-epiestriol and

4-hydroxy-estrone [6] In addition to the substrates accepted by

UGT2B4, UGT2B7 is able to glucuronidate various

steroid hormones (androsterone, epitestosterone) and

fatty acids [7] UGT2B4 and UGT2B7 therefore play a

key role in the detoxification of cholestatic bile acids

and may prevent the formation of proximal

carcino-gens such as quinone estrocarcino-gens In addition, UGT2B7

is also able to conjugate major classes of drugs such as

analgesics (morphine), carboxylic nonsteroidal

anti-inflammatory drugs (ketoprofen) and anticarcinogens

(all-trans retinoic acid) However, the molecular basis

of the overlapping substrate specificity of these enzymes

remains to be elucidated

Several studies have highlighted the role of the

N-ter-minal domain of UGTs in substrate specificity, and

many lines of evidence indicated that it may contain the

major structural determinants for substrate recognition

The organization of the UGT1A complex locus suggests

that the N-terminal part encoded by separate exons 1

governs the individual substrate specificity of each

iso-form, whereas the identical C-terminal halves, encoded

by exons 2–5, would interact with the common

co-sub-strate, UDP-glucuronic acid [8] In addition, Mackenzie

[9] showed that exchanging the N-terminal half between

two rat UGT2B isoforms, UGT2B2 and UGT2B3,

resulted in a switch-over of their respective substrate

selectivity In agreement, Li et al [10] showed that

replacement of the C-terminal part of rabbit UGT2B16

with its counterpart in UGT2B13 did not change the

specificity of this isoform

The aim of this study was to identify amino acid

res-idues that are involved in substrate specificity of

UGTs 2B4 and 2B7 in order to better understand the

molecular basis of substrate recognition and catalysis

by these enzymes Attention was paid to amino acids

at the N-terminal end of these UGTs, as this region is

believed to interact with the substrates, although the

contribution of the C-terminal part cannot be totally

excluded Mutation of phenylalanine at position 33 at

the N-terminus of UGT2B4 was specifically carried

out, as we have discovered that this residue was

substi-tuted by leucine, in a UGT2B4 variant cDNA that

was previously described by Jin et al [11] to encode a

UGT2B4 deficient in HDCA glucuronidation activity

As the phenylalanine residue at position 33 in the UGT2B4 isoform was replaced by tyrosine in UGT2B7, the mutation of this residue into leucine

in UGT2B7 was also performed We also mutated the phenylalanine 33 residue of UGT2B4 into the tyrosine residue found at the same position in UGT2B7 and carried out the corresponding mutations in UGT2B7, namely UGT2B7Y33L and UGT2B7Y33F The results demonstrated the critical importance of an aromatic amino acid at position 33 for the activity and substrate specificity of both UGT2B4 and UGT2B7

Results The phenylalanine residue at position 33 of UGT2B4 is important for substrate specificity of the enzyme towards HDCA Investigation of the deficiency in HDCA glucuronidation by the UGT2B4 variant described by Jin et al [11] led to the discovery of the previously unreported mutation of phenylalanine resi-due 33 to leucine Sequence alignment showed that all UGT2B members contained either a phenylalanine or tyrosine residue at this position (Fig 1) In order to determine the effect of phenylalanine at position 33 on HDCA glucuronidation, this residue was replaced by leucine, creating the UGT2B4F33L mutant and expressed in baculovirus-infected insect cells As illustra-ted in Fig 2, immunoblot analysis of the membrane fraction of these cells showed that the full-length protein was produced The expression level of each UGT in the current set of recombinant enzymes, mutants as well as wild-types, was determined by dot-blot analyses using monoclonal antibodies, as previously described [19] The substrate specificity of UGT2B4F33L mutant was evaluated towards HDCA and a range of steroids and phenolic compounds in addition to carboxylic acids and was compared to that of the wild-type UGT2B4 (Fig 3) The results confirmed that both 17-epiestriol

Fig 1 Sequence alignment of the region encompassing residue 33

of several UGTs of subfamily 2B The alignment was performed using the program resident in GCG DNA and Protein Analysis Package (Promega, Madison, WI, USA) The fully conserved amino acids in this alignment are indicated by bold font.

and HDCA were efficiently glucuronidated by this

iso-form (Fig 3A) In addition, we show here that

UGT2B4 could also glucuronidate bulky and planar

phenols (eugenol, 4-hydroxybiphenyl and 1-naphthol)

In contrast, other steroids such as testosterone and

17a-ethynylestradiol were not accepted The carboxylic

nonsteroidal anti-inflammatory drug ketoprofen or the

anti-HIV drug 3¢-azido-3¢-deoxythymidine were

conju-gated at a very low rate (Fig 3A) Altogether, the

results of this substrate screening indicated that

UGT2B4 is able to transfer glucuronic acid onto

struc-turally diverse substrates, with a marked preference for

17-epiestriol, HDCA and phenolic substrates

The activity profile of the UGT2B4F33L mutant

showed a selective change in substrate preference

(Fig 3B) Indeed, the mutant was unable to

glucuroni-date HDCA, and its activity towards phenolic

sub-strates, as well as the steroids 4-hydroxyestrone and

17-epiestriol was strongly affected (Fig 3B) Apparent

kinetic constants of the wild-type UGT2B4 and of the

mutant were evaluated and Vmax values were

normal-ized according to the level of protein expression

(Table 1) In the case of 4-hydroxyestrone and 17-epi-estriol, the Km values of the mutant enzymes were increased by six- and two-fold, respectively, compared

Fig 2 Western blot analyses of the enzymes included in this

study The gels were loaded with 2, 10 or 100 lg of membrane

proteins for UGT2B4, UGT2B4F33L and UGT2B4F33Y, respectively

(A), or 12, 15 or 15 lg of membrane proteins for UGT2B7,

UGT2-B7Y33L and UGT2B7Y33F, respectively (B) The UGTs were probed

with primary antibody directed against the His-tag, and the second

antibodies were horseradish-peroxidase-conjugated anti-mouse Ig.

The blot was then developed using LumiGLO TM

A

(pmol/min/mg protein) 0

25 50 75 100

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16

UGT2B4

Substrates

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16

B

UGT2B4F33L

Substrates 0

0.5 1.0 1.5 2.0

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16

C

Substrates 0

25 50 75 100

UGT2B4F33Y

Fig 3 Glucuronidation activity of UGT2B4 (A) and UGT2B4 mutants (B, C) for the probe substrates 1, 4-Methylumbelliferone; 2, euge-nol; 3, hyodeoxycholic acid (HDCA); 4, androsterone; 5, testoster-one; 6, epitestostertestoster-one; 7, b-estradiol; 8, 17a-ethynylestradiol; 9, 4-hydroxyestrone; 10, 17-epiestriol; 11, 4-hydroxybiphenyl; 12, 4-iso-propylphenol; 13, 4-nitrophenol; 14, 1-naphthol; 15, RS-ketoprofen;

16, 3¢-azido-3¢deoxytymidine The enzyme reaction was carried out with 50 lg protein and was incubated with 0.02 m M

UDP-glucuron-ic acid containing 0.1 lCi UDP-[14C]glucuronic acid and 0.5 m M sub-strate as indicated in Experimental procedures The glucuronides were separated by thin layer chromatography, visualized by auto-radiography (shown in insert) and quantitated by liquid scintillation counting The rate values are the mean of three experiments The film was exposed for four days in the case of UGT2B4 and UGT2B4F33Y and for one week in the case of UGT2B4Y33L.

with wild-type UGT2B4 The Vmax values showed a

decrease of 19- and 34-fold for 4-hydroxyestrone and

17a-epiestriol, respectively (Table 1)

The primary structure of UGT2B7 is 87% identical

to that of UGT2B4 with 76 differences out of 528

amino acids, including 55 differences in the first 300

amino acids of the N-terminus Both enzymes share

common substrates, including HDCA [6] This led us

to compare the N-terminal amino acid sequence of

UGT2B4 and UGT2B7, predicted from its cDNA, in

the region encompassing residue 33 (Fig 1) The

ana-lysis revealed that residue F33 of UGT2B4 was

replaced by Y33 in UGT2B7 Therefore, we have also

constructed and expressed in Sf9 cells a UGT2B4

mutant in which F33 was replaced by tyrosine,

gener-ating the mutant UGT2B4F33Y (Fig 2) Analysis of

the glucuronidation activity of this mutant showed an

activity profile similar to the wild-type UGT2B4

Moreover, HDCA and 4-hydroxyestrone were even

more efficiently glucuronidated by the mutant

(Fig 3C, Table 1) Kinetic analysis indicated that the

Kmand Vmaxvalues of UGT2B4F33Y towards HDCA

and 4-hydroxyestrone were increased by 3.5- and

two-fold, and by 4.6- and three-two-fold, respectively,

com-pared with UGT2B4 (Table 1) These results led us to

hypothesize that the aromatic tyrosine residue at

posi-tion 33 in UGT2B4 may play an important role in the

substrate specificity of the isoform

Importance of amino acid residue tyrosine 33

in the substrate specificity of UGT2B7

The wild-type UGT2B7 efficiently glucuronidates

17-epiestriol and eugenol and, in comparison with

UGT2B4, it exhibited a marked preference for

4-hydroxyestrone and HDCA (Table 1) In addition, UGT2B7 efficiently glucuronidated androsterone and epitestosterone (Fig 4A) To investigate whether the tyrosine residue at position 33 in UGT2B7 plays a role in HDCA glucuronidation and substrate specifi-city, we substituted this residue by leucine, as found in the HDCA-deficient UGT2B4 variant, and expressed the mutant in insect cells (Fig 2)

Analysis of the activity of the UGT2B7Y33L mutant towards various substrates showed that replacement of Y33 by leucine resulted in a dramatic change in activity and substrate specificity of UGT2B7 (Fig 4, compare parts A and B) Indeed, the mutation abolished glucu-ronidation of several substrates including phenols such

as 1-naphthol and steroids such as androsterone and b-estradiol (Fig 4B), and greatly reduced the activity towards HDCA and 4-hydroxyestrone (Fig 4B, Table 1) In addition, glucuronidation of bulky phen-ols, 4-hydroxybiphenyl and 4-isopropylphenol, and the steroid epitestosterone was dramatically decreased On the other hand, the activity towards 17-epiestriol was increased by the Y33L mutation in UGT2B7 (Table 1) These data showed that the presence of a leucine resi-due at position 33, instead of tyrosine, led to an enzyme with restricted and somewhat modified specific-ity Further kinetic characterization of this mutant indicated that the Km values towards HDCA and 17-epiestriol were in the same range as that of the wild-type However, the Kmvalue towards 4-hydroxyestrone was decreased by six-fold (Table 1) Furthermore, the

Vmax values underwent major changes, with 20- and 25-fold decrease for HDCA and 4-hydroxyestrone, respectively, and 1.2-fold increase for 17-epiestriol

In contrast to leucine residue, replacement of tyro-sine by phenylalanine at position 33 of UGT2B7 had

Table 1 Apparent K m and normalized V max values for glucuronidation of selected substrates by wild-type UGT2B4 and UGT2B7 and mutants Kinetic parameters were evaluated from initial velocity values of the reaction performed in triplicates using varying concentrations

of substrates (0–1 m M ) at a constant concentration of UDP-glucuronic acid (0.5 m M ) Expression of wild-type and mutants was evaluated as described in the Experimental procedures and expressed relative to UGT2B4 or UGT2B7 ND, not determined, due to lack of detectable activity.

UGT

HDCA

Relative protein expression (%)

V max

(pmolÆmin)1Æ

mg)1Æprotein)

K m

l M

V max

(pmolÆmin)1Æ

mg)1Æprotein)

K m

l M

V max

(pmolÆmin)1Æ

mg)1Æprotein)

K m

l M

only a minor effect on activity and substrate

specifi-city The mutant UGT2B7Y33F exhibited similar

sub-strate specificity as wild-type UGT2B7 (Fig 4C) and

kinetic analysis indicated that the Km values towards

HDCA and 17-epiestriol were increased by about

two-and three-fold, respectively The Vmax value towards

4-hydroxyestrone was decreased by two-fold and it

was increased by two- and six-fold for HDCA and 17-epiestriol, respectively (Table 1) These experiments highlighted the importance of an aromatic residue at position 33 in the capacity of UGT2B7 to glucuroni-date a broad range of aglycone substrates

Discussion

A major property of the UGTs is their large and over-lapping substrate specificity, which confers to glucuroni-dation a significant role in the detoxification processes This characteristic feature is typically illustrated from comparison of the activity of UGT2B4 and UGT2B7, which are both able to glucuronidate HDCA and cate-chol-estrogens as well as xenobiotics, as shown in this and other studies [5] However, UGT2B7 has a broader specificity than UGT2B4 and it is able to accommodate various steroids such as androsterone and epitestoster-one The molecular basis of the substrate selectivity of these enzymes is difficult to understand because no com-mon structural features between the substrates glucuro-nidated by each isoform were thus far found [12] This general assessment prompted us to identify amino acids that may account for the substrate specific-ity of these UGTs The high sequence homology between UGT2B4 and UGT2B7, in combination with a marked difference in substrate specificity, especially towards steroid substrates, was favorable for attempt-ing to pinpoint the amino acid residues that are critical for the substrate specificity In the current study, we have shown that the presence of an aromatic residue at position 33 of UGT2B4 and UGT2B7 is important in that respect This conclusion is based on the following lines of evidence: (a) the UGT2B4F33L mutant exhib-ited a strong decrease in HDCA glucuronidation; (b) the UGT2B4F33Y mutant was able to sustain the glucuronidation of both HDCA and 4-hydroxyestrone; (c) mutation of residue Y33 of UGT2B7 to leucine led

to an enzyme with a restricted substrate specificity; and (d) the mutant UGT2B7Y33F exhibited similar activity and substrate specificity to those of UGT2B7 Interest-ingly, Villeneuve et al [13] recently reported a novel polymorphism of the UGT1A9 isoform, whose muta-tion M33T (corresponding to posimuta-tion 31 in UGT2B4) was responsible for a large decrease in the activity (by 96%) of the glucuronidation of the anticancer drug, SN-38 In contrast, the activity measured with flavo-piridol was unaffected, indicating that, similar to our findings, a single mutation can affect enzyme activity for a subset of aglycones substrates The above study

by Villeneuve et al [13] and our work emphasize the crucial role of the region encompassing residue at posi-tion 33 in the substrate specificity of UGT isoforms

A

Substrates

2 3 4 5 6 7 8 9 10 11 12 13 1415 16

1

0

150

300

600

750

B

Substrates

UGT2B7Y33L

16

2 3 4 5 6 7 8 9 10 11 121314 15

1

0

50

75

100

25

C

UGT2B7Y33F

2 3 4 5 6 7 8 9 10 11 12 13 14 15 16

1

Substrates 0

600

1500

300

750

450

150

Fig 4 Glucuronidation activity of UGT2B7 (A) and UGT2B7Y33L

mutant (B) for probe substrates Numbers refer to substrates as in

Fig 3 The insert shows the glucuronides separated by thin layer

chromatography and visualized by autoradiography (All the films

were exposed for 4 days.) Activities were measured as indicated in

the legend to Fig 3 and are the mean of three experiments.

The changes in specificity observed for the different

mutants were characterized further by kinetic analyses

The results with UGT2B4F33L revealed that the

impairment in 4-hydroxyestrone and 17-epiestriol

glucu-ronidation efficacy resulted from a large increase in Km

values, along with a decrease in the Vmax values These

data suggest that the mutations primarily affect binding

of the substrates, but they do not rule out the possibility

of a reduced access of the substrate to the catalytic site

upon mutation On the other hand, replacement of F33

by tyrosine led to mutant UGT2B4F33Y with similar

substrate specificity as the wild-type enzyme

support-ing the idea that a tyrosine can substitute to the

wild-type phenylalanine residue Moreover, mutant

UGT2B4F33Y exhibited enhanced glucuronidation

towards HDCA and 4-hydroxyestrone compared with

wild-type The kinetic parameters of the mutant

indica-ted an increase in both Vmaxand Kmvalues (Table 1)

In the case of UGT2B7, substitution of Y33 to

leu-cine led to a severe restriction in aglycones accepted by

the enzyme In fact, the effects of replacing the

aroma-tic residue at position 33 by leucine on the substrate

specificity of UGT2B7 were even more dramatic than

in UGT2B4 Only three out of the 12 compounds

pre-viously glucuronidated by UGT2B7 remained

effi-ciently glucuronidated by the UGT2B7Y33L mutant

Nonetheless, the Kmvalue for HDCA was not

signifi-cantly different from that obtained for the wild-type

enzyme, suggesting that the affinity of the enzyme for

HDCA was not largely altered by the mutation In the

case of 4-hydroxyestrone glucuronidation, the Km

indi-cated an enhanced apparent affinity of the mutant

For both substrates, the mutation decreased the Vmax

values On the other hand, the Vmax of the mutant

towards 17-epiestriol was slightly increased and the Km

was not significantly modified

Replacement of the Y33 residue of UGT2B7 by

phe-nylalanine led to a mutant, UGT2B7Y33F, with even

more enhanced glucuronidation activity towards

HDCA and 17-epiestriol compared with the wild-type

Analyses of the kinetic parameters of the

UGT2-B7Y33F mutant indicated enhanced Vmax and Km

values, except for 4-hydroxyestrone, which showed a

two-fold decrease in the Vmvalue (Table 1)

Taken together, the results of this study are

consis-tent with the notion that residue 33 is involved in the

interactions of the enzyme with the substrate in both

UGT2B4 and UGT2B7

In contrast to the F33L mutation, which reduces the

activity of UGT2B4 and UGT2B7, exchanging F33 for

tyrosine sustained the enzyme activity and specificity

Although a leucine residue can establish hydrophobic

interactions, it will produce more steric hindrance than

an aromatic residue such as phenylalanine or tyrosine

In agreement with this proposal, a tyrosine residue at position 33 in UGT2B4 was able to support glucuroni-dation of HDCA, thus suggesting that p-stacking interactions and⁄ or steric hindrance conferred by an aromatic residue are critical for access or recognition

of this substrate Steric hindrance by a critical residue has been proposed as an underlying principle that can regulate substrate and⁄ or product specificities of enzymes catalyzing the metabolism of hydrophobic substrates For example, the phenylalanine residue at position 87 of cytochrome P450 BM-3 was suggested

to act through steric hindrance to determine the regio-and stereospecificity of the arachidonic acid epoxy-genase activity [14] Such a situation is also exemplified

in the case of estrogen sulfotransferase, which posses-ses two critical aromatic residues forming a gate-like structure that was suggested to confer estrogen specifi-city to this enzyme [15]

The involvement of several residues in determining the substrate specificity probably also stands true for the UGTs Coffman et al [16] reported the important role of the aspartic residue at position 99 of UGT2B7

in the binding of morphine When this charged amino acid was substituted with alanine, a dramatic decrease

in activity was observed In agreement, the structure– function analysis of UGT2B15 and UGT2B17 sugges-ted that a set of residues (including residue 121) is implicated in the steroid specificity of these isoenzymes [17] These studies, along with our work, indicate that substitution of a single amino acid can substantially affect substrate recognition, but multiple differences between two related isoforms probably contribute to their individual specificity

In conclusion, this study shows, for the first time, that

an aromatic residue at position 33 is critical for the sub-strate specificity of UGT2B4 and UGT2B7 The data provide the basis with which to modulate the substrate specificity of human UGT isoforms by protein engineering

Experimental procedures Chemicals and reagents

4-Methylumbelliferone (free acid), 1-naphthol, 4-nitro-phenol, 4-hydroxybiphenyl, 4-hydroxyestrone, 17a-ethinyl-estradiol, testosterone, eugenol, HDCA, androsterone, epitestosterone, b-estradiol, 17-epiestriol, isopropylphenol, ketoprofen, 3¢-azido-3¢-deoxythymidine and UDP-glucuro-nic acid (sodium salt) were purchased from Sigma (L’Isle d’Abeau, St Quentin Fallavier, France) UDP-[U-14 C]-glucuronic acid (418 mCiÆmmol)1) was obtained from NEN (Perkin Elmer, Courtaboeuf, France) Restriction enzymes

were provided by New England Biolabs (Hitchin, UK) The

QuikChange site-directed mutagenesis kit was from

Strata-gene (La Jolla, CA, USA), LumiGLOTM was from Cell

Signaling (Beverly, MA, USA), and Advantage 2

poly-merase mix was from Clontech (Palo Alto, CA, USA) All

other reagents were of the best quality and commercially

available

Expression vectors constructions

Expression vectors used to express human UGT2B4 and

UGT2B7 with an apparent molecular mass of about

53 kDa in baculovirus-infected insect cells were previously

described [18] The short C-terminal extension, including a

His-tag, was added by subcloning the respective cDNAs

into the modified shuttle vector pFBXHA to generate

2B4-XHA and 2B7-2B4-XHA expression vectors [18]

Site-directed mutagenesis

Construction of amino acid substituted mutants of

UGT2B4 and UGT2B7 were performed using the

Quik-Change site-directed mutagenesis kit according to the

recommendations of the manufacturer 2B4-XHA and

2B7-XHA expression vectors were used as a template The

sequence of the sense and antisense mutation primers is

indicated in Table 2 Full-length mutated cDNAs were

sys-tematically checked by DNA sequencing

Heterologous expression in insect Sf9 cells

Wild-type UGT2B4 and UGT2B7 and mutants expression

vectors were transfected in the Escherichia coli strain

DH10Bac for the generation of recombinant ‘bacmids’

that, in turn, were employed for the production of

recom-binant baculovirus stocks according to the Bac-to-Bac

procedure (Invitrogen, Cergy Pontoise, France) The

pro-duction of recombinant proteins was carried out following

optimization trials in which the suitable amount of virus

from the new stocks for the infection of insect Sf9

cells was estimated The relative expression level of

each UGT in microsomal membranes was evaluated by

immunodetection using the monoclonal His-tag anti-body Tetra-His (Qiagen, Hilden, Germany) as described previously [19]

Western blot analysis was performed by loading onto the gel 2, 10 and 100 lg of membrane proteins for UGT2B4, UGT2B4F33L and UGT2B4F33Y, respectively, and 12, 15 and 15 lg of membrane proteins for UGT2B7, UGT2-B7Y33L and UGT2B7Y33F, respectively The proteins were separated in 10% SDS⁄ PAGE gels, transferred to a polyvinylidene difluoride membrane (Millipore, Eschborn, Germany), and subsequently blocked in Tris-buffer saline-Tween 20 containing 5% nonfat milk Membranes were incubated overnight with monoclonal anti-His-tag antibody Tetra-His directed against His-tag followed by incubation with horseradish-peroxidase-conjugated secondary antibod-ies The blot was then developed using LumiGLOTM according to the instructions of the manufacturer (Cell Signaling, Danvers, MA, USA)

Analysis of glucuronidation activity Protein concentration was measured as previously described [20] with the Bio-Rad reagent (Bio-Rad, Hercules, CA, USA) The activity of the recombinant wild-type and mutant UGT2B4 and UGT2B7 towards several substrates was determined as described [21] Briefly, incubation in Eppendorf tubes (total volume 40 lL) consisted of 50 lg of microsomal proteins for UGT2B7, UGT2B7Y33L, UGT2-B7Y33F and UGT2B4 and 200 lg for UGT2B4F33Y and UGT2B4F33L in 100 mm Tris⁄ HCl buffer (pH 7.4), 10 mm MgCl2 containing 0.02 mm UDP-glucuronic acid and 0.1 lCi UDP-[U-14C]glucuronic acid The reaction was star-ted by addition of substrate (0.5 mm final concentration) dissolved in 2 lL dimethylsulfoxide A control was per-formed in which the substrate was omitted and dimethyl-sulfoxide added After incubation for 1 h at 37C, the proteins were precipitated by 40 lL ethanol in ice, and removed by centrifugation at 4000 g for 10 min at 4C The supernatant was loaded onto thin layer chromato-graphy plates (LK6DF silica gel, 250 lm; Whatman, Clif-ton, NJ, USA) The plates were developed with n-butanol, acetone, acetic acid, aqueous ammoniac (28%), water

Table 2 Sequence of the primers used for site-directed mutagenesis Mutant amino acid codons are underlined.

(70 : 50 : 18 : 1.5 : 60 v⁄ v) They were dried and sprayed

with 1% (v⁄ v) 2-(4-t-butylphenyl)-5()4-biphenyl)-1,3,

4-oxadiazole in toluene The radioactivity associated with

the glucuronide was visualized by autoradiography with

X-Omat Kodak films (Sigma) for 3 days at)20 C The

sil-ica gel areas of the glucuronides were scraped off and the

associated radioactivity was quantified on a LKB

spectro-meter using Fluoran Safe Ultima Gold scintillant cocktail

(Packard, Rungis, France) The decomposition per min

value in a given sample was considered significant when it

was at least two-fold of that of the blank sample

Kinetic analysis of the data

Kinetic parameters were evaluated from initial velocity

val-ues of the reaction performed as described above Varying

concentrations of the substrates (0–1 mm) at a constant

concentration of UDP-GlcA (0.5 mm) were used Km and

Vmaxvalues for HDCA, 4-hydroxyestrone and 17a-epiestriol

were determined using nonlinear least square analysis of

the data fitted to Michaelis-Menten rate equation (v¼

Vmax· [S] ⁄ Km+ [S]), where S is the substrate and v is

the velocity, using the curve-fitter program sigmaplot 9.0

[22]

Acknowledgements

This work was supported by grants from Ligue Contre

le Cancer Re´gion Lorraine, Agence Nationale de la

Recherche (ANR number NT05-3_42251) and Re´gion

Lorraine, as well as the Academy of Finland (Project

210933) We thank J, Mosorin for excellent technical

assistance and PI Mackenzie (Flinders University,

Adelaide, Australia) for kindly providing the UGT2B4

variant cDNA

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