Tài liệu Báo cáo khoa học: Plasticity of laccase generated by homeologous recombination in yeast docx

From transformants secreting active variants, three chimeric laccases LAC131, LAC232 and LAC535, each resulting from double crossovers, were purified, and their apparent kinetic parameter

recombination in yeast

Angela M Cusano*,, Yasmina Mekmouche*, Emese Meglecz and Thierry Tron

Laboratoire Biosciences, Institut des Sciences Mole´culaires de Marseille, Universite´ Aix-Marseille, ISM2 CNRS UMR 6263, Marseille Cedex

20, France

Keywords

cupredoxin domains; functional hybrids;

heterologous expression; multicopper

enzyme; recombination

Correspondence

T Tron, Laboratoire Biosciences, Institut

des Sciences Mole´culaires de Marseille,

Universite´ Aix-Marseille, ISM2 CNRS UMR

6263, Avenue Escadrille Normandie

Niemen, case 342, F-13397 Marseille Cedex

20, France

Fax: +33 491 288440

Tel: +33 491 289196

E-mail: thierry.tron@univ-cezanne.fr

*These authors contributed equally to this

work

Present addresses

INRA NANCY, UMR 1136

Interactions Arbres–Micro-organismes,

Equipe de Pathologie Forestie`re, Route

d’amance, 54280 Champenoux,

France

IMEP, Case 36, Universite´ de Provence,

3 Place Victor Hugo, 13331 Marseille

Cedex 3, France

Database

The sequences of the laccase hybrid cDNAs

lac131, lac232 and lac 535 have been

sub-mitted to the GenBank database under the

accession numbers FJ817449, FJ817450

and FJ817451, respectively

(Received 28 May 2009, revised 9 July

2009, accepted 23 July 2009)

doi:10.1111/j.1742-4658.2009.07231.x

Laccase-encoding sequences sharing 65–71% identity were shuffled in vivo

by homeologous recombination Yeast efficiently repaired linearized plas-mids containing clac1, clac2 or clac5 Trametes sp C30 cDNAs using a clac3 PCR fragment From transformants secreting active variants, three chimeric laccases (LAC131, LAC232 and LAC535), each resulting from double crossovers, were purified, and their apparent kinetic parameters were determined using 2,2¢-azino-bis(3-ethylbenzthiazoline-6-sulphonic acid) and syringaldazine (SGZ) as substrates At acidic pH, the apparent kinetic parameters of the chimera were not distinguishable from each other or from those obtained for the LAC3 enzyme used as reference On the other hand, the pH tolerance of the variants was visibly extended towards alka-line pH values Compared to the parental LAC3, a 31-fold increase in apparent kcatwas observed for LAC131 at pH 8 This factor is one of the highest ever observed for laccase in a single mutagenesis step

Abbreviations

ABTS, 2,2’-azino-bis(3-ethylbenzthiazoline-6-sulphonic acid); BCBD, blue copper binding domain; bp, base pair; SGZ, syringaldazine

(4-hydroxy-3,5-dimethoxybenzaldehyde azine).

cluster is responsible for O2 reduction [1] The overall

outcome of the catalytic cycle is reduction of one

mole-cule of dioxygen into two molemole-cules of water, coupled

with oxidation of four substrate molecules (phenols or

anilines) into four radicals that can form dimers,

oligo-mers and polyoligo-mers These enzymes are common in

plants, fungi, insects and bacteria [2,3]

Laccases are intensely studied for their potential uses

in industrial processes They generally work under

mild conditions: room temperature and atmospheric

pressure, with water as solvent [4–7] Over the past

decade, a significant number of reports focusing on

applications of this eco-friendly enzyme in

technologi-cal and bioremediation processes, in addition to their

use in organic synthesis, have been published [5] For

industrial use, the current challenge is to obtain both

enhanced expression levels and improved laccases with

desirable physicochemical characters such as a higher

redox potential, optimal activity at neutral or alkaline

pH, and thermostability [8] Strategies to obtain such

variants include natural biodiversity screening and

optimization of nature-derived scaffolds

Mutagenesis (rational or random) is often used to

generate laccase variants In their pioneering work, Xu

et al [9] have reported significant changes in pH

opti-mum, KM and kcat for triply mutated fungal laccases

Replacement of the aspartic acid D206 by alanine in a

Trametes versicolor laccase resulted in a threefold

increase in kcat[10] A similar improvement factor was

also reported for variants found in simple libraries of

in vitrorandomly generated mutants from Fomes

ligno-sus[11] or Pleurotus ostreatus [12] On the other hand,

combination of in vitro mutation and in vivo

recombi-nation strategies to evolve a Myceliophthora

thermo-phila laccase led to a 170-fold increase in total laccase

activity, corresponding to a 22-fold improvement in

kcat[13] In a recent report, a similar approach allowed

authors to isolate a variant of a M thermophila laccase

capable of resisting a wide array of co-solvents at

con-centrations as high as 50% v⁄ v [14] In all available

examples of molecular evolution of laccase, variants

with improved properties have been derived from

lac-case sequences from a single origin at a time

Com-pared to the shuffling of randomly mutated sequences,

DNA ends as efficient substrates for homologous recombination, the gap repair methodology allow effi-cient rescue of a replicative linearized plasmid by inter-molecular recombination within co-introduced sequence-related DNA On the other hand, it has been shown that recombination involving similar but not identical DNA sequences (homeologous DNA) can occurs at rates proportional to the length of homology [15,16] Thus, some groups have used in vivo homeolo-gous recombination to yield low-complexity chimeric enzymes [15–17] Usually, a chimera generated in vivo results from the shuffling of large blocks of sequence corresponding to one or more structural domains When high-complexity chimeric enzymes are desired,

in vitro recombination methods, either random [18,19]

or structure-oriented [20], are preferred

The scaffold of laccases and related copper-contain-ing proteins of various functions (e.g bacterial nitrite reductase, plant ascorbate oxidase, the E coli metallo-oxidase CueO, human ceruloplasmin etc.) consist of repeats of a homologous sequence domain (blue cop-per-binding domain) that shares distant homology to the single-domain cupredoxins [21,22] The evolution-ary path from a single-domain cupredoxin to a three-domain laccase (D1, D2, D3) is thought to involve a duplication of genes and recruitment of a domain [22] During evolution from an electron transfer protein to

an oxidase, proto-laccase lost unnecessary blue copper-binding sites (in D1 and D2), acquired a T2–T3 cluster binding site (the dioxygen reduction site mapping at the boundary of D1 and D3) and substrate-binding sites (one for the electron donor and one for O2) in neo-formed clefts [21,22] (see Fig 1)

Taking inspiration from evolutionary pathways within the blue copper binding domain (BCBD) protein family, we aim to evolve laccases into artificial catalysts performing new activities In a first approach, basic protein engineering techniques – such as fusion

of laccase with an interacting domain [23] – were used

to explore properties of simple artificial laccases expressed in heterologous hosts Here, we report on the construction of laccase chimeras through yeast-mediated homeologous recombination of Trametes sp strain C30 laccase cDNAs sharing 65–71% identity

Active variants of laccase were selected directly on

transformation plates Expression, purification and

analysis of the pH activity profile allowed the

charac-terization of a variant of laccase presenting unusual

oxidation activity at pH 8 corresponding to a

substan-tial increase in kcat

Results

Homeologous recombination of laccase-encoding

sequences

Chimeric laccase-encoding sequences were obtained in

three independent homeologous intermolecular

recom-bination experiments In each experiment, two parental

laccase-encoding cDNAs were introduced in yeast by

co-transformation of a linearized expression vector,

containing either clac1, clac2 or clac5, in the presence

of an overlapping double-stranded PCR fragment of

clac3 Upon transformation, intermolecular

recombina-tion within the homeologous sequences led to

re-circu-larization of the replicative plasmid, and yeast

transformants were selected on the plasmid-borne

URA3 marker without selection for the point of

recombination between the homeologous genes The

frequency of recombination ranged from 102 (cla535)

to 104 (cla131 and cla232) transformants per lg of

DNA The frequency of recombination depends on the

homology of the sequences that are being recombined,

and therefore frequencies one to two orders of

magni-tude lower than the frequencies reported for the

recombination of homologous sequences [15] probably

reflect the level of identity between the sequences we

used (cla1 versus clac3, 68.4%; cla2 versus clac3, 71%;

cla5versus clac3, 65.3%)

Among the transformants, active laccase-secreting

clones were detected as those able to oxidize the

2-meth-oxyphenol present in the selective medium Plasmids

recovered from these transformants were first analysed

by restriction mapping in order to confirm their hybrid nature (results not shown) and then sequenced Hybrid laccase-encoding genes lac131, lac232 and lac535 obtained by recombination were all found to contain a clac3 central sequence (700–800 bp) (Fig 1) In recom-binant sequences, junctions were found to map within short stretches of identity varying from 5–45 bp Similar lengths for 5¢ and 3¢ recombination zones were found in other randomly picked clones (data not shown)

Deduced amino acid sequences of LAC131, LAC232 and LAC535 hybrids were found to resemble more clo-sely that of LAC3 (89, 94 and 85% identity, respec-tively) than that of either LAC1 (81%), LAC2 (83%)

or LAC5 (83%) All together, recombination induced swapping of amino acids for 94 positions (19% of the residues) in the original LAC3 sequence The C- and N-termini of the hybrids were 33–37% and 9–26%

different, respectively, from that of LAC3

Expression, purification and characterization of the laccase hybrids

LAC3 and the LAC131, LAC232 and LAC535 hybrids were heterologously expressed in Saccharomyces cerevi-siaeW303-1A, and extracellular laccase production was analysed The production levels in the hybrids were on average six times lower than observed for LAC3 (300 UÆL)1 versus 2000 UÆL)1 using SGZ) This may

be due either to differences in the activity of the enzymes or differences in expression conditions (differ-ent plasmid context, glycosylation level etc.; see below and Discussion) Recombinant laccases were purified from 10 L fermentor cultures in three steps according to our previous protocol [24] For all these enzymes, we obtained a yield of 20% of pure enzyme, with a specific activity of 300 UÆmg)1 determined in acetate buffer (0.1 m, pH 5.5) using SGZ as the substrate

A B

Fig 1 Schematic representation of gene structures obtained in intermolecular recombination assays (A) Parental (lac1, lac2, lac3 and lac5)

and hybrid (lac131, lac232 and lac535) sequences are represented by rectangles of variable lengths Recombinant junctions are indicated by

vertical bars (B) Representation of cupredoxin domain organization in the laccase structure Black diamond, T1 copper atom; black circle, T2

copper atom; white circle, T3 copper atoms.

The apparent molecular mass of LAC3 and hybrids

estimated by SDS–PAGE was found to be substantially

higher than that expected from the amino acid sequences

(Fig 2) Previous analysis on LAC3 has suggested that

these differences are due to N-hyperglycosylation, a

well-known process occurring during expression of

for-eign proteins in S cerevisiae [25] Among the laccases

studied, the apparent molecular mass of LAC535

(approximately 79 kDa) was slightly lower than that

observed for the three other proteins (approximately

87 kDa), probably because of the replacement of

N-gly-cosylation sites during the recombination process This

is supported by an in silico analysis of the hybrid amino

acid sequences, which indicated that the LAC535

sequence contains two potential N-glycosylation sites

fewer than the other sequences (data not shown)

Kinetic results

The apparent kinetic parameters measured for LAC3

and hybrids using

2,2¢-azino-bis(3-ethylbenzthiazoline-6-sulphonic acid) (ABTS) and syringaldazine as

substrates are reported in Table 1 At pH 5.7 (in Mes

metric substrate, as ABTS is known to be stable at 4.0£ pH £ 11.0 [26] (Fig 3) Various patterns of activ-ity were observed from pH 6.0–8.0, with LAC131 and LAC232 having substantial activity at neutral to alka-line pH (Fig 3) Similar behaviour was observed with SGZ as substrate, but precipitation and reversible transformation of SGZ at neutral pH led us to discon-tinue this experiment with this substrate Based on these initial observations, we recorded the kinetics of ABTS oxidation for LAC3 and the three hybrids in Britton–Robinson buffer at various pH within a pH range of 4.5–8.0 As expected from previous reports on laccase kinetics, the catalytic efficiency of the tested enzymes towards ABTS decreased rapidly as pH increased, reaching values < 10% of the original (i.e

at pH 4.5) between pH 7.5 and 8.0 Variations in the apparent KM, kcat and kcat⁄ KM values as function of

pH were plotted Below pH 6.0, all enzymes behaved almost identically Above pH 6.0, the apparent KM value for LAC131 was almost stable (a threefold decrease was observed at pH 8.0), whereas the values for LAC3, LAC232 and LAC535 were 10–20 times lower than those observed at acidic pH Apparent kcat values decreased rapidly, but the enzymes appeared to

be differently affected: the apparent kcat values for LAC3 and LAC535 were three orders of magnitude lower than the corresponding values at pH 5.0, whereas LAC232 and LAC131 values were reduced by factors of 500 and 50, respectively (Table 2) Thus, between pH 4.5 and 8.0, the LAC3 and LAC535 enzymes appear undistinguishable from a kinetic point

of view On the other hand, the LAC131 and LAC232 enzymes appear to be more tolerant to alkaline pH, as their activity profiles were found to be shifted by at

Fig 2 Coomassie staining of 8% SDS–PAGE of purified laccase

enzymes Lane 1, LAC3; lane 2, LAC131; lane 3, LAC232; lane 4,

LAC535; lane M, molecular mass standards (kDa) Each well

contained 4 lg of protein.

Table 1 Apparent kinetic parameter values for SGZ and ABTS in 50 m M MES buffer, pH 5.7, at 30 C.

Enzyme

k cat (min)1) K M (l M ) k cat ⁄ K M (min)1Æl M )1) k

cat (min)1) K M (l M ) k cat ⁄ K M (min)1Æl M )1)

least one pH unit toward alkalinity Relative to the

LAC3 parental enzyme, if one considers a higher

activity at pH 8.0 as an improvement, the apparent

kcat values for the LAC232 and LAC131 enzymes

improved 5- and 31-fold, respectively (Fig 4) In terms

of catalytic efficiency, this corresponds to

improve-ments of 5- and 12-fold, respectively

Discussion

Basidiomycete genomes contain multiple genes

encod-ing laccase isoenzymes, with large variations in identity

(for example ranging from 38–86% in Coprinopsis

cine-rea [27]) This natural diversity within in a single

organism can be used for protein engineering purpose

In Trametes sp C30, we previously characterized five

genes [24,28–31], four of which encoded expressed

pro-teins and were used here for molecular breeding

experi-ments The lac131, lac232 and lac535 hybrid genes

contain more than half of the lac3 gene sequence,

flanked by the 5¢ and 3¢ lac1, lac2 and lac5 regions,

respectively In all three chimeric genes, the recombina-tion points between parental sequences more than

1500 nucleotides long involve less than 50 nucleotides However, in the donor sequence (lac3), the 5¢ recombi-nation zone (279 nucleotides long) is about five times larger than the 3¢ one (58 nucleotides long) In the 5¢ recombination zone, blocks of identical nucleotides are short and spread over the entire segment (66% overall identity within the four sequences), whereas in a win-dow of comparable size (about 280 nucleotides) cen-tred on the 3¢ recombination zone, the highest identity

is found in the central 58 nucleotide block (87% over-all identity within the four sequences) Studying ho-meologous recombination of P450 sequences, Me´zard

et al [16] concluded that the preferred points of recombination could be those corresponding to maxi-mal identity in the overall alignment of the parental sequences However, the short window of recombina-tion found in the 3¢ zone suggests a bias in the selec-tion of recombinaselec-tion points It has been suggested that optimal recombination points allow swapping of structural blocks [19], and combination of large pro-tein fragments in our chimera led to fully functional enzymes Moreover, as recombination of nature-selected sequences is conservative [32], crossovers lead-ing to functional hybrids occur at positions that mini-mize disruption of interactions [18] In the chimera, recombination preserved the integrity of domain D1 and the very end part of domain D3, two regions that interact precisely in the natural laccase fold (Fig 5) Because of the bias introduced by linearization of the receptor fragment at restriction sites, it is difficult to interpret the position of the recombination points rela-tive to domain D2 However, it seems that D2⁄ D3 interactions are favoured in the chimera (all LAC3), whereas D1⁄ D2 interactions are favoured only in

Fig 3 Variations in ABTS oxidation rates as function of pH for

LAC3 and the hybrids LAC131, LAC232 and LAC535 ABTS

(5.5 m M final concentration) was added to the appropriate enzyme

solution (0.6 nM) at the desired pH Oxidation rates are proportional

to variations in the absorbance at 410 nm per minute and are

indi-cated as DA⁄ min Inset: microtitre plate with enzyme ⁄ substrate

mixtures at various pH values; the photograph was taken after

3 min of incubation at 30 C.

Table 2 Apparent kinetic parameter values for ABTS at various pH

in Britton–Robinson buffer adjusted to the relevant pH at 30 C.

Enzyme

k cat (min)1) K M (l M )

kcat⁄ K M (min)1Æl M )1)

pH 5.0 pH 8.0 pH 5.0 pH 8.0 pH 5.0 pH 8.0

Fig 4 Relative increase in apparent k cat for laccase hybrids as a function of pH.

LAC535 (all LAC5) Nevertheless, the 5¢

recombina-tion points apparently match structural block limits in

chimeras as junctions were found: at the limit of

domain D2 in LAC131, at the limit of domain D1 in

LAC232, and at the position (or nearby) of the

cyste-ine residue C228 (LAC3 numbering) that is involved in

a disulfur bridge with C140 (D1) in LAC535 Based on

the present observations, a better knowledge on

toler-ance to block exchange in the laccase enzyme should

be obtained by in vitro sequence permutation

experi-ments and swapping of cupredoxin domains (D1, D2,

D3) Such experiments are in progress

One of the beneficial effects of production of the

present Trametes sp C30 laccase chimeras was to

create hybrid sequences that are better expressed in the

host than the parental sequences clac1, clac2 and clac5 Among the parental sequences used for this recombi-nation study, only constructions bearing the sequence encoding the LAC3 isoenzyme have previously been found to lead to substantial production of recombinant enzyme in yeast [29,30] Whereas LAC1 and LAC2 have been purified and fully characterized from Tra-metes sp C30 [28,31], their recombinant counterparts produced in yeast are barely detectable on activity plates (T Tron, unpublished results) These differences

in expression of recombinant enzyme coding sequences are likely largely related to inappropriate codon usage

by the heterologous host, as low-frequency codons can cause translation pauses depending on their position and abundance Upon recombination with clac3

Fig 5 Molecular models of LAC3 and hybrids Models were constructed using the structure of the laccase 2HRG from T trogii as template.

A ribbon representation is used for the LAC3 model; copper atoms are represented as grey spheres; the p-methylbenzoate present in the structure 2HRG is used in the models to indicate a potential substrate-interacting zone A surface representation is used for the hybrids; the surface of the parts of hybrids originating from LAC3 is coloured in light blue; the surface of the parts of hybrids originating from either LAC1, LAC2 or LAC5 but identical to LAC3 is coloured in dark blue; the surfaces of the parts of hybrids corresponding to LAC1, LAC2 or LAC5 substitutions are coloured in yellow, red and magenta, respectively.

sequence, the clac1-, clac2- and clac5-based

construc-tions led to functional expression of the hybrid

sequences clac131, clac232 and clac535 A simple

inspection of coding preference plots [33] for the

parental and chimeric sequences confirmed that

exchanging large sequence segments with the clac3

sequence substantially reduces the number of codons

that potentially cause translation pauses During

func-tional expression of a M thermoplila laccase gene in

S cerevisiae by directed evolution, synonymous

muta-tions to more frequently used codons improved

pro-duction of the recombinant laccase up to eightfold

[13] For our laccase chimera, it is difficult to calculate

a fold improvement in production relative to LAC1,

LAC2 or LAC5 because of the absence of a reference

level for these parental enzymes On the other hand,

compared to LAC3, as the steady-state kinetic

parame-ters for all the enzymes are of the same order of

mag-nitude, the ratio of the total volumetric activities

reflects a decrease in production by the hybrids of

approximately fivefold This suggests that the codon

usage can probably be improved further, for example

through design of synthetic sequences

LAC3 is representative of a class of laccases found

in basidiomycetes: it is an acidic enzyme that works

best in a pH window from 4.5–6.0 Under catalysis

conditions previously established for LAC3 (buffer,

pH, temperature), all three variants are as active as

LAC3 This is remarkable as a 60–90% decrease in

activity has been reported for P450 chimera (similar to

our laccases in sequence size, identity, recombination

area), although, in this case, chimera activities may

account both for intrinsic kinetic differences in

sub-strate oxidation and differences in interaction with a

reductase [16] In our case, as discussed above,

recom-bination essentially preserved domain interactions as

well as the architecture of coordination sites

More-over, the substrate-interacting zone, as defined by the

location of substrate analogues in the crystal structures

of Coriolaceae laccases 1KIA [34] and 2HRG (http://

www.rcsb.org), is identical to that of the LAC3

enzyme, either because it is entirely composed of

LAC3 sequence (LAC131, LAC232) or because residue

variations in that zone are conservative (LAC535)

(Fig 5) These may be major reasons why the kinetic

behaviour of the hybrids is closer to that of LAC3

rather than that of the other parental enzymes [28,31]

Like other basidiomycetous laccases, LAC3 variant

activities are progressively inhibited by an increasing

concentration of OH)[35], which binds the T2 copper,

but significant differences distinguish them from each

other Thus, the LAC3 and LAC535 pH profiles are

superimposable, suggesting strong conservation of the

original LAC3 properties upon recombination, although the protein sequence of this hybrid is the least related to that of LAC3 (Fig 5) On the other hand, LAC131 and LAC232 hybrids oxidize ABTS 31- and 5-fold faster, respectively, than the parental LAC3 enzyme at pH 8.0 As the kinetic behaviour of all of our enzymes is very similar below pH 6.0, these results probably reflect a significant improvement in the stabil-ity of LAC131 and LAC232 hybrids at alkaline pH Further studies on this type of mutants should help to deepen our knowledge on protein regions modulating laccase activity in response to pH changes

In conclusion, recombination of large fragments of sequence coding for laccase isoenzymes leads to the exchange of structural blocks, allowing synthesis of hybrid enzymes with properties that distinguish them from the parental enzymes Differences in laccase activity observed at pH 8.0 do not reflect an enhance-ment in kcat but rather reflect an enhancement of the enzyme stability at alkaline pH Nevertheless, the cata-lytic efficiency of the best-performing hybrid (LAC131)

is more than 12 times that of the parental enzyme (LAC3) Compared to studies involving mutagenesis, such a factor is one of the highest ever observed in a single step Thus, hybrids obtained by homeologous recombination constitute a valuable tool set to study the plasticity of the enzyme

Experimental procedures

Materials and reagents Chemicals were purchased from Sigma-Aldrich (St Louis,

MO, USA) and were of the highest available grade The Britton–Robinson buffer was produced by mixing 0.1 m boric acid, 0.1 m acetic acid and 0.1 m phosphoric acid with 45% NaOH to the desired pH 2-(N-morpholino)ethane-sulfonic acid (Mes) buffer was adjusted to pH 5.7 with NaOH Spectroscopic measurements were performed using either a CARRY 50 spectrophotometer (Varian, Palo Alto,

CA, USA) or a KC4 microtitre plate reader (BioTek, Winooski, VT, USA) A DuoFlow FPLC apparatus (Bio-Rad, Hercules, CA, USA) was used for chromatographic separations

Strains and vectors used for cloning and expression

S cerevisiae W303-1A (MATD, ade2-1, his3-11, 15, leu2-3/112, trp1-1, ura3-1, can1-100) was used for expression of laccase Yeast expression vector pDP51 (2l, Ampr, URA3, GAL10⁄ CYC1) pBM258 (GAL1⁄ GAL10, CEN4⁄ ARS1, Ampr, URA3) and pSAL4 (2l, Ampr, URA3, CUP1) were

The four parental laccase-encoding sequences clac1, clac2,

clac3and clac5 have been previously isolated from Trametes

sp strain C30 and heterologously expressed in S cerevisiae

in our laboratory [24,29–31] Expression vectors bearing

clac1 (AKY160), clac2 (EMY162) or clac5 (EMY164)

sequences were linearized at the SmaI, Kpn2I and ClaI

restriction sites, respectively, located in the laccase-coding

region The clac3 sequence was amplified by PCR from the

construct pAKY145 [29,30] using EM53 (5¢-TTCCTTTTG

GCTGGTTTTGC-3¢) and EM54 (5¢-CAGTTATTACCC

TATGCGGTGTGA-3¢), respectively, as forward and

reverse primers The resulting 2015 bp amplicon was

gel-purified and further used in co-transformation assays (lg

donor DNA/lg vector DNA=4) with various linearized

laccase-encoding vectors Transformants were plated on

selective medium (per litre: yeast nitrogen base without

amino acids and ammonium sulfate, 6.7 g; casaminoacids,

5 g; adenine sulfate, 30 mg; CuSO4100 lm; succinate buffer

50 mm, pH 5.3; 1.5% agar) containing 2% galactose as the

carbon source and 0.05% v⁄ v guaı¨acol as the laccase

substrate Laccase-active transformants were picked and

further studied

Enzyme production

Yeasts were cultivated at 28C Pre-cultures were obtained

in two stages from a single colony freshly grown on a

selec-tive plate Cells were first grown in 15 mL tubes containing

5 mL of selective medium for 24 h on a rotating wheel A

volume of suspension sufficient to reach a final attenuance

at 600 nm of 0.1 was then used to inoculate 250 mL

Erlen-meyer flasks containing 50 mL of selective medium, and cells

were then grown for 24 h on a reciprocal shaker (150 rpm)

Bio-reactor cultivations (batch) were performed in a 15 L

fermentor vessel (B Braun Biotech International GmbH,

Melsungen, Germany) containing 10 L of selective medium

The inoculum was added to a final attenuance at 600 nm of

0.1, and yeasts were grown under stirring (220 rpm) and

with an air flow of 16 LÆh)1 Samples (1 mL) to be used

for laccase activity and cell density determination were

withdrawn and analysed regularly throughout cultivation

Purification

Cells were sedimented by centrifugation at 1600 g and 4C

for 10 min Culture supernatant (10 L) was successively

many) pre-equilibrated with the same buffer Proteins were eluted at a flow rate of 4 mLÆmin)1with a step gradient of NaCl: 0.1, 0.15, 0.2, 0.25, 0.3 and 1 m Fractions containing laccase activity were pooled and concentrated to a volume

of 600 lL by ultrafiltration on a 25 mm diameter YM10 membrane, and loaded on a Superdex S200 column (Amer-sham Pharmacia) equilibrated with 20 mm phosphate, pH 6.0, 200 mm NaCl Fractions containing laccase activity were pooled and concentrated Exchange with buffer con-taining no salt, concentration and addition of 15% glycerol were undertaken for long-term storage of the protein ()20 C) Enzyme purity in active fractions was then con-firmed by SDS–PAGE

Standard enzyme assay Protein concentration was determined by the Bradford method using BSA as standard, or by UV-vis spectroscopy (e600 nm= 5· 103m)1Æcm)1 for the T1 copper) [37] Lac-case activity was routinely assayed at 30C using SGZ as the substrate Oxidation of SGZ was detected by measuring the absorbance increase at 525 nm (e525nm= 6.5· 104

m)1Æcm)1) after 2 min using a spectrometer (Carry 50 UV-vis spectrophotometer) [38] The reaction mixture (1 mL) contained 10 lL of appropriately diluted enzyme sample and 980 lL of Mes buffer (50 mm, pH 5.7), and 10 lL of 0.8 mgÆmL)1SGZ in MeOH was added to initiate the reac-tion One unit (U) of laccase oxidizes one micromole of substrate per minute

Kinetic parameter determination and effect of pH Determination of kinetics parameters was undertaken using two substrates: SGZ and ABTS For SGZ, the same condi-tions were used as those for the standard enzyme assay ABTS oxidation was determined in both MES and Britton– Robinson buffers by monitoring the absorbance change at

414 nm with an extinction coefficient of 3.5· 104m)1Æcm)1 [39] Variation of the ABTS oxidation rate as function of

pH was assayed in a 96-well plate at 30C for 2 min using Britton–Robinson buffer adjusted to a pH from 4.5–8.0 Apparent KMand kcatvalues were obtained from the initial rate (v), enzyme concentration (E) and substrate concentra-tion (S) according to the equaconcentra-tion v = kcatE S⁄ (KM+ S) (non-linear regression fitting using prizm program,

Graph-pad, San Diego, CA) Because laccase catalysis involves

two substrates and the [O2] was invariant and assumed to

be saturating in this study, the measured KMfor the

vari-ous substrates used should be considered apparent Because

of the assumption that 100% of the laccase participated in

the catalysis as active enzyme, the measured kcat should

also be considered apparent

Molecular models

3D models were obtained from the Swiss Model Server

(swissmodel.expasy.org) using the crystallographic

coordi-nates from Trametes trogii laccase 2HRG obtained from

the Research Collaboratory for Structural Bioinformatics

(RCSB) Protein Data Bank (http://www.rcsb.org)

Acknowledgements

This work was partly supported by the European

Commission, Sixth Framework Program

(NMP2-CT2004-505899, SOPHIED) Angela Cusano was the

recipient of a Re´gion Provence Alpes Coˆte d’Azur

Postdoc fellowship Emese Meglecz was the recipient

of a Ministe´re de le Recherche Postdoc fellowship We

thank Marius Re´glier, Jalila Simaan, Erin

Wallace-Bomati and Gilles Iacazio (Laboratoire Biosciences,

Institut des Sciences Mole´culaires de Marseille,

Univer-site´ Aix-Marseille, France) for helpful discussions

References

1 Solomon EI, Sundaram UM & Machonkin TE (1996)

Multicopper oxidases and oxygenases Chem Rev 96,

2563–2605

2 Baldrian P (2006) Fungal laccases – occurrence and

properties FEMS Microbiol Rev 30, 215–242

3 Gianfreda L, Xu F & Bollag J-M (1999) Laccases: a

useful group of oxidoreductive enzymes Bioremediat J

3, 1–25

4 Faber K (2004) Biotransformations in Organic

Chemis-try Springer, Berlin

5 Riva S (2006) Laccases: blue enzymes for green

chemis-try Trends Biotechnol 24, 219–226

6 Rodrı´guez Couto S & Tocca Herrera J (2006) Industrial

and biotechnological applications of laccases: a review

Biotechnol Adv 24, 500–513

7 Wells A, Teria M & Eve T (2006) Green oxidations

with laccase-mediator systems Biochem Soc Trans 34,

304–308

8 Zuma´rraga M, Camarero S, Shleev S, Martı´nez-Arias

A, Ballesteros A, Plou FJ & Alcalde M (2008) Altering

the laccase functionality by in vivo assembly of mutant

libraries with different mutational spectra Proteins 71,

250–260

9 Xu F, Berka RM, Wahleithner JA, Nelson BA, Shuster

JR, Brown SH, Palmer AE & Solomon EI (1998) Site-directed mutations in fungal laccase: effect on redox potential, activity and pH profile Biochem J 334, 63–70

10 Madzak C, Mimmi MC, Caminade E, Brault A, Baumberger S, Briozzo P, Mougin C & Jolivalt C (2006) Shifting the optimal pH of activity for a laccase from the fungus Trametes versicolor by structure-based mutagenesis Protein Eng Des Sel 19, 77–84

11 Hu MR, Chao YP, Zhang GQ, Yang XQ, Xue ZQ & Qian SJ (2007) Molecular evolution of Fome lignosus laccase by ethyl methane sulfonate-based random muta-genesis in vitro Biomol Eng 24, 619–624

12 Festa G, Autore F, Fraternali F, Giardina P & Sannia

G (2008) Development of new laccases by directed evo-lution: functional and computational analyses Proteins

72, 25–34

13 Bulter T, Alcalde M, Sieber V, Meinhold P, Schlacht-bauer C & Arnold FH (2003) Functional expression of

a fungal laccase in Saccharomyces cerevisiae by directed evolution Appl Environ Microbiol 69, 987–995

14 Zumarraga M, Bulter T, Shleev S, Polaina J, Martinez-Arias A, Plou FJ, Ballesteros A & Alcalde M (2007)

In vitroevolution of a fungal laccase in high concentra-tions of organic cosolvents Chem Biol 14, 1052–1064

15 Me´zard C & Nicolas A (1994) Homologous, homeolo-gous, and illegitimate repair of double-strand breaks during transformation of a wild-type strain and a rad52 mutant strain of Saccharomyces cerevisiae Mol Cell Biol 14, 1278–1292

16 Me´zard C, Pompon D & Nicolas A (1992) Recombina-tion between similar but not identical DNA sequences during yeast transformation occurs within short stretches of identity Cell 70, 659–670

17 Volkov AA, Shao Z & Arnold FH (1999) Recombina-tion and chimeragenesis by in vitro heteroduplex forma-tion and in vivo repair Nucleic Acids Res 27, e18

18 Crameri A, Raillard S, Bermudez E & Stemmer WP (1998) DNA shuffling of a family of genes from diverse species accelerates directed evolution Nature 391, 288– 291

19 Ostermeier M, Nixon AE & Benkovic SJ (1999) Incre-mental truncation as a strategy in the engineering of novel biocatalysts Bioorg Med Chem 10, 2139–2144

20 Voigt CA, Martinez C, Wang ZG, Mayo SL & Arnold

FH (2002) Protein building blocks preserved by recom-bination Nat Struct Biol 9, 553–558

21 Nakamura K & Go N (2005) Function and molecular evolution of multicopper blue proteins Cell Mol Life Sci 62, 2050–2066

22 Nersissian AM & Shipp EL (2002) Blue copper-binding domains Adv Protein Chem 60, 271–340

23 Balland V, Hureau C, Cusano AM, Liu Y, Tron T & Limoges B (2008) Oriented immobilization of a fully

binant fungal laccases and bilirubin oxidase that exhibit

significant differences in redox potential, substrate

speci-ficity, and stability Biochim Biophys Acta 1292, 303–311

27 Kilaru S, Hoegger PJ & Ku¨es U (2006) The laccase

multi-gene family in Coprinopsis cinerea has seventeen

different members that divide into two distinct

subfami-lies Curr Genet 50, 45–60

28 Dedeyan B, Klonowska A, Tagger S, Tron T, Iacazio

G, Gil G & Le Petit J (2000) Biochemical and

molecu-lar characterization of a laccase from

Marasmi-us quercophilMarasmi-us Appl Environ Microbiol 66, 925–929

29 Klonowska A (2000) Expression he´te´rologue de laccases

du champignon Marasmius quercophilus chez la levure

Saccharomyces cerevisiae PhD Thesis, Universite´

Aix-Marseille III, Marseille, France

30 Klonowska A, Gaudin C, Asso M, Fournel A, Reglier M

& Tron T (2005) LAC3, a new low redox potential

lac-case from Trametes sp strain C30 obtained as a

recombi-nant protein in yeast Enzyme Microb Technol 36, 34–41

31 Klonowska A, Gaudin C, Fournel A, Asso M, Le Petit

J, Giorgi M & Tron T (2002) Characterization of a low

Madzak C & Mougin C (2002) Crystal structure of a four-copper laccase complexed with an arylamine: insights into substrate recognition and correlation with kinetics Biochemistry 41, 7325–7333

35 Xu F (1997) Effects of redox potential and hydroxide inhibition on the pH activity profile of fungal laccases

J Biol Chem 272, 924–928

36 Sambrook J, Fritsch EF & Maniatis T (1989) Molecular Cloning: A Laboratory Manual Cold Spring Harbor Laboratory Press, Cold Spring Harbor, New York

37 Bradford M (1976) A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein–dye binding Anal Biochem 2, 248–254

38 Bauer R & Rupe CO (1971) Use of syringaldazine in a photometric method for estimating ‘free’ chlorine in water Anal Chem 43, 421–425

39 Childs RE & Bardsley WG (1975) The steady-state kinetics of peroxidase with 2,2¢-azino-di-(3-ethyl-benz-thiazoline-6-sulphonic acid) as chromogen Biochem J

45, 93–103