Báo cáo khóa học: Furanocoumarin biosynthesis in Ammi majus L. Cloning of bergaptol O-methyltransferase ppt

Distinct O-methyltransferase activities had been reported to methylate bergaptol to bergapten and xantho-toxol to xanthotoxin, from induced cell cultures of Ruta graveolens, Petroselinum

Furanocoumarin biosynthesis in Ammi majus L.

Cloning of bergaptol O -methyltransferase

Marc Hehmann1,*, Richard Lukacˇin1,*, Halina Ekiert2and Ulrich Matern1

1

Institut fu¨r Pharmazeutische Biologie, Philipps-Universita¨t Marburg, Germany;2Department of Pharmaceutical Botany,

Collegium Medicum, Jagiellonian University, Krako´w, Poland

Plants belonging to the Apiaceae or Rutaceae accumulate

methoxylated psoralens, such as bergapten or xanthotoxin,

as the final products of their furanocoumarin biosynthesis,

and the rate of accumulation depends on environmental and

other cues Distinct O-methyltransferase activities had been

reported to methylate bergaptol to bergapten and

xantho-toxol to xanthotoxin, from induced cell cultures of Ruta

graveolens, Petroselinum crispum and Ammi majus

Bergap-tol 5-O-methyltransferase (BMT) cDNA was cloned from

dark-grown Ammi majus L cells treated with a crude fungal

elicitor The translated polypeptide of 38.7 kDa, composed

of 354 amino acids, revealed considerable sequence

similar-ity to heterologous caffeic acid 3-O-methyltransferases

(COMTs) For homologous comparison, COMT was

cloned from A majus plants and shown to share 64%

identity and about 79% similarity with the BMT sequence at

the polypeptide level Functional expression of both enzymes

in Escherichia coli revealed that the BMT activity in the

bacterial extracts was labile and rapidly lost on purification,

whereas the COMT activity remained stable Furthermore,

the recombinant AmBMT, which was most active in potassium phosphate buffer of pH 8 at 42
C, showed narrow substrate specificity for bergaptol (Km SAM6.5 lM;

Km Bergaptol 2.8 lM) when assayed with a variety of sub-strates, including xanthotoxol, while the AmCOMT accep-ted 5-hydroxyferulic acid, esculetin and other substrates Dark-grown A majus cells expressed significant BMT activity which nevertheless increased sevenfold within 8 h upon the addition of elicitor and reached a transient maxi-mum at 8–11 h, whereas the COMT activity was rather low and did not respond to the elicitation Complementary Northern blotting revealed that the BMT transcript abun-dance increased to a maximum at 7 h, while only a weak constitutive signal was observed for the COMT transcript The AmBMT sequence thus represents a novel database accession specific for the biosynthesis of psoralens Keywords: Ammi majus L.; Apiaceae; furanocoumarin biosynthesis; bergaptol O-methyltransferase; caffeate O-methyltransferase

Cell suspension cultures of the Apiaceae, in particular Ammi

majusL [1,2] and Petroselinum crispum [3–6], have served

in numerous model studies on the induced plant disease

resistance response Upon treatment with fungal elicitor,

these cells produce linear furanocoumarins (psoralens)

besides lignin-like compounds for reinforcement of their cell

walls [7–9] Various crude cell wall elicitors, particularly Pmg

(from Phythophthora sojae, formerly Phythophthora

mega-sperma f.sp glycinea), have been used in the past, and at least

in case of the induction of parsley cells the eliciting principle

has been identified as a peptide [10] Furanocoumarins are potentially toxic compounds which probably function as phytoalexins in the response to fungal infection [3], but their accumulation can also be triggered by other means, e.g wounding of plants or exposure to acid fog [11,12] A considerable proportion of psoralens may be recovered from the surface of plants [13], and most of the psoralens elicited in cell cultures also accumulated in the culture fluid Psoralens are capable of intercalating with DNA, and the methoxyl-ated psoralens bergapten and xanthotoxin are the most relevant natural furanocoumarins in terms of their thera-peutic potential These psoralens exhibit photosensitizing and antiproliferative activities [14] and were evaluated as photosensitizing drugs in oral psoralen plus UVA irradiation (PUVA) therapy of psoriasis and vitiligo [15,16]

A majuscells also uniquely produce derivatives of 7-O-prenylumbelliferone under conditions of elicitation (Fig 1) [17], and the induction of coumarin biosynthesis in these cell cultures provided the basis for extensive in vitro investiga-tions Both the umbelliferone 7-O-prenyltransferase activity and a 6-C-prenyltransferase activity forming demethylsube-rosin en route to the psoralens (Fig 1) were found associated with the microsomal fraction [18] Such a 6-C-prenyltransferase activity had been reported initially as a

Mn2+-dependent enzyme from Ruta graveolens and assigned to the plasitidic membranes [19] Individual

Correspondence to U Matern, Institut fu¨r Pharmazeutische Biologie,

Philipps-Universita¨t Marburg, Deutschhausstrasse 17A,

D-35037 Marburg, Germany.

Fax: + 49 6421 282 6678, Tel.: + 49 6421 282 2461,

E-mail: matern@staff.uni-marburg.de

Abbreviations: SAM, S-adenosyl- L -methionine; BMT, bergaptol

5-O-methyltransferase; XMT, xanthotoxol 8-O-methyltransferase;

OMT, O-methyltransferase; COMT, caffeic acid

3-O-methyltrans-ferase; PUVA, psoralen plus UVA irradiation; RACE, rapid

amplification of cDNA ends; RLM-RACE, RNA ligase-mediated

rapid amplification of cDNA ends.

*These authors contributed equally to the work described.

(Received 3 November 2003, revised 17 December 2003,

accepted 15 January 2004)

cytochrome P450 monooxygenases sequentially convert

demethylsuberosin to (+)-marmesin and psoralen, and

these activities were also demonstrated in the microsomal

fraction of elicited A majus cells [1,2] Moreover, the

conversion of (+)-marmesin to psoralen (Fig 1) was

proven to proceed by syn-elimination releasing acetone

[20] The subsequent hydroxylation of psoralen in the 5- or

8-position yields bergaptol and xanthotoxol, respectively

(Fig 1) Both of these hydroxylations to yield

5,8-dihyd-roxypsoralen are required for the formation of

isopimpin-ellin, which commonly accumulates as a minor byproduct

upon induction, but the order of hydroxylations and

O-methylations remains unresolved [19] However, psoralen

5-monooxygenase activity forming bergaptol was

demon-strated in vitro with microsomes from elicited A majus cells

[2] The biosynthesis of bergaptol from umbelliferone is

thus entirely catalyzed through membrane-bound enzymes,

involving one prenyltransferase and three P450

monoxy-genases, and is preceded by the formation of umbelliferone

from 4-coumaric acid, which was also proposed to depend

on a P450 monooxygenase The 5- or 8-hydroxylated

furanocoumarins (bergaptol or xanthotoxol) are further

processed by O-methylation to bergapten and xanthotoxin,

and the corresponding O-methyltransferases (OMTs) were

identified as distinct entities and purified by affinity chromatography from Ruta graveolens [21] and later also from Petroselinum crispum [22] S-Adenosyl-L-methionine– bergaptol 5-O-methyltransferase (SAM–BMT) and S-aden-osyl-L-methionine–xanthotoxol 8-O-methyltransferase (SAM–XMT) (Fig 1) are also expressed in dark-grown

A majuscells, and in all instances these methyltransferases are soluble and inducible enzymes

We report here the cloning and functional characteriza-tion of BMT from elicitor-treated Ammi majus L cells as a major step towards a molecular understanding of psoralen biosynthesis For comparison, the closely related S-adeno-syl-L-methionine–caffeate 3-O-methyltransferase (SAM– COMT) was also cloned from A majus plants, and the differential regulation of these methyltransferases was examined upon elicitation of the cell cultures

Materials and methods

Ammi majus cell cultures and induction Cell suspension cultures of A majus L (40 mL B5+ -medium in 250 mL flasks) were initiated and grown continuously in the dark as described elsewhere [1,2] Pmg

Fig 1 Schematic outline of linear

furanocou-marin biosynthesis The sequence of

hydroxy-lations and O-methyhydroxy-lations of psoralen

leading to isopimpinellin has not been

established.

elicitor was suspended in distilled water (5 mgÆmL)1), the

suspension was heated to boiling point and added to

6-day-old cell cultures (1 mL per 40 mL culture) The cells were

harvested 4 h later and immediately frozen in liquid

nitrogen and stored at)70
C until use

Chemicals

Biochemicals were purchased from Roth (Karlsruhe,

Germany), vectors and Escherichia coli host strains from

Invitrogen (Karlsruhe, Germany) or Qiagen (Hilden,

Germany) Restriction enzymes and DNA modifying

enzymes were from MBI-Fermentas (St Leon-Rot,

Germany), Promega (Mannheim, Germany) or Stratagene

(Heidelberg, Germany) Bergaptol was bought from

Extrasynthese (Genay, France), caffeic acid from Roth

(Karlsruhe, Germany), and [methyl-14

C]S-adenosyl-L-methionine was purchased from Hartmann Analytic

(Braunschweig, Germany)

RNA isolation, PCR cloning and heterologous

expression

Total RNA was isolated from Pmg elicitor-induced cells

following the protocol of Giuliano et al [23] The time

of elicitor-induction was chosen from previous induction

experiments in which the time course of

furanocoumarin-specific enzyme activities in A majus had been monitored

[1,2] Alternatively, the RNA was isolated from the stems

and leaves of 4–6 week-old A majus plants cDNA

frag-ments were generated by RT-PCR amplification using

degenerate oligonucleotide primers [24] which had been

designed according to conserved amino acid sequences of

plant OMTs [25,26] The cDNA fragments were cloned,

sequenced, and full length clones were generated by the

rapid ampification of cDNA ends (RACE) and RNA

ligase-mediated rapid amplification of cDNA ends

(RLM-RACE) techniques, respectively, using gene-specific

pri-mers Cloning of the PCR products was performed by

TOPO TA Cloning (Invitrogen, Karlsruhe, Germany)

Briefly, the protein coding regions of the putative BMT

and COMT were amplified with 5¢-primers providing an

NcoI site directly before the start codon and 3¢-primers

inserting a BamHI site after the stop codon before they were

cloned into the pCR2.1-TOPO vector An internal NcoI site

contained in the ORF of the COMT was deleted by using

QuikChange Multi Site-Directed Mutagenesis Kit as

described by the manufacturer (Stratagene, Heidelberg,

Germany) without altering the amino acid sequence The

mutation was verified by DNA sequencing [27], and the

BMT- and COMT-coding DNA clones were subsequently

isolated by digestion with NcoI and BamHI The cDNAs

were subcloned into pQE60 vector (Qiagen, Hilden,

Germany) for functional expression in E coli strain M15

(Qiagen) harboring the plasmid pRep4 and employed for

BMT and COMT activity assays, respectively The

expres-sion was induced by the addition of 1.0 mMisopropyl

thio-b-D-galactoside [28] Following the induction, the cells were

harvested by centrifugation [29], disrupted by

ultrasonica-tion, the crude extract was cleared by centrifugation

(30 000 g, 4
C, 10 min), and enzyme assays were carried

out with the supernatants

Sequence analysis The cDNAs amplified by RT-PCR were sequenced by the dideoxy nucleotide chain termination technique [27] The cDNA sequences were subjected to BLAST searches (advanced WU-Blast2; EMBL) and alignments with

CLUSTALWalgorithm (EMBL)

Purification procedure The crude extract was fractionated by ammonium sulfate precipitation from 0 to 45%, 45–60% and 60–80% saturation The 60–80% fraction (BMT) and the 45–60% fraction (COMT) were dissolved in 200 mM

potassium phosphate buffer of pH 8.0 and 200 mM Tris/ HCl buffer of pH 7.5, respectively The extracts were desalted by size exclusion chromatography

columns (Amersham, Freiburg, Germany) and on Frac-togel EMD BioSEC (S) (Merck, Darmstadt, Germany) The purification was monitored by SDS/PAGE [30] and enzyme activity assays of individual fractions

Enzyme assays and other analytical methods BMT activity was routinely measured at 42
C in 200 mM

potassium phosphate buffer pH 8.0 in the presence of sodium ascorbate (20 mM), magnesium chloride (1.5 mM), bergaptol (250 lM) and the recombinant bacterial enzyme extract The reaction was started by the addition

of S-adenosyl-L-[methyl-14C]methionine (40 lM), and the product was identified as bergapten by silica thin-layer chromatography employing trichloromethane/ethylacetate (2 : 1, v/v; RF bergaptol0.52, RF bergapten0.77), trichlorometh-ane/methanol (95 : 5, v/v; RF bergaptol0.26, RF bergapten0.78), n-hexane/ethylacetate/methanol (5 : 5 : 1, v/v/v; RF bergaptol

0.67, RF bergapten 0.78) or toluene/ethylacetate (3 : 2, v/v;

RF bergaptol0.34, RF bergapten0.68) as the solvent systems The COMT activity assay was carried out at 32
C in 200 mM

potassium phosphate buffer pH 7.5 containing sodium ascorbate (20 mM), magnesium chloride (1.5 mM), caffeic acid (250 lM) and S-adenosyl-L-[methyl-14C]methionine (40 lM) in addition to

reactions were stopped by the addition of 1M

and extracted with 400 lL ethyl acetate Aliquots of the organic phase (200 lL) were mixed with 5 mL scintillation cocktail (Roth, Karlsruhe, Germany) and measured in a liquid scintillation counter (1214 Rackbeta; PerkinElmer, Wellesley, MA, USA) Incubations with boiled enzyme (5 min at 100
C), or mixtures lacking bergaptol and caffeic acid, were run for control and served for background corrections

Linear conditions for kinetic assays were established by adjusting the amount of enzyme protein (BMT: 0.15–3.0 lg per assay; COMT: 0.5–10.25 lg per assay) The BMT assays were usually conducted for 20 min, using 1.5 lg desalted protein and 4.0 nmol S-adenosyl-L-[methyl-14C]methionine and 25.0 nmol bergaptol per 100 lL incubation, which secured linear conversion rates for about 60 min The COMT assays were carried out accordingly using 5 lg desalted protein Protein was determined according Lowry et al [31] and the data were extrapolated from Lineweaver–Burk plots

Northern blotting

Following the addition of Pmg elicitor to the A majus cell

suspensions, total RNA was isolated from the cells every

0.5 h up to 8 h and used for Northern blot analysis (RNA

dot blot) The RNA (4 lg) was denaturated in 0.5· Mops

buffer pH 6.0, containing 50% (v/v) formamide and 2.2M

formaldehyde, and transferred to a Hybond-N+ nylon

membrane (Amersham Biosciences, Freiburg) [32] in an

I-SRc 96-Dot Blot Minifold (Schleicher and Schu¨ll, Dassel,

Germany) The full size A majus BMT cDNA (1062 bp)

and COMT cDNA (1095 bp) were 32P-labeled using a

RediprimeTMII-random prime labeling system (Amersham

Biosciences, Freiburg), and used as probes The blots were

blocked and then hybridized with 25 ng of one of these two

labeled probes Hybridization was carried out overnight

at 68
C in 2· Denhardt’s solution in the presence of 0.5%

(w/v) SDS and 100 lgÆmL)1salmon sperm DNA (Sigma,

Deisenhofen, Germany) After stringent washings for

20 min at room temperature in 2· NaCl/Cit followed by

15 min at 68
C in 2· NaCl/Cit the membranes were

exposed to a Bio Imaging Analyzer FLA-2000 (Fujifilm)

Results

Induction ofO-methyltransferase activities

Elicitor–induction studies had been carried out previously

with A majus cell cultures, and the coumarin-specific

enzyme activities (dimethylallyldiphosphate: umbelliferone

6-C- and 7-O-dimethylallyltransferases) commonly reached

a first maximum at 12 h of induction [18] This time course

suggested maximal transcript abundances within the first

6 h of elicitation and corresponded to the patterns reported

for the elicitor induction of phenylalanine ammonia lyase

and 4-coumarate:CoA ligase activities in Petroselinum

crispumcell cultures [33] However, a different induction

profile was reported by Hauffe et al [22] for the BMT

activity in P crispum cells with a maximum beyond 25 h

Therefore, preliminary assays of BMT and XMT activities

were conducted with crude extracts of dark-grown A majus

cells and under the conditions described for Ruta graveolens

[34] These assays revealed that both O-methyltransferase

activities were expressed already in the controls (0.4 lkatÆ

kg)1BMT and 66 nkatÆkg)1XMT, on average), but

increased considerably in response to treatment of the cell

suspensions with Pmg elicitor The activities were measured

every three hours over the time period from 2 to 23 h

following the addition of elicitor, and shown to increase

sevenfold within 8 h to reach a transient maximum at about

8–11 h (H Ekiert and R Lukacˇin, unpublished data)

Thus, the cells at 4 h after the addition of elicitor were

considered to contain the highest BMT and XMT transcript

abundances

The activity of COMT in A majus was examined for

comparison, and only low levels (2.5 lkatÆkg)1on average)

were observed in crude extracts of suspension-cultured cells,

which hardly changed upon elicitation and might be due to

related OMTs with specificity towards catechols [26,35]

However, higher activity (4.2 lkatÆkg)1) was determined in

extracts of leaf and stem tissues The moderate rate of

COMT expression in the suspension cells is reminiscent of

the correspondingly low COMT activity in cultured Petro-selinum crispumcells [36] In Petroselinum as well as in Ruta cells, the COMT activity had been clearly distinguished from the BMT and XMT activities [22,34]

cDNA cloning and functional expression The total RNA from A majus cells that had been elicited for 4 h was used as a template for RT-PCR amplifications, with degenerate oligonucleotide primers designed for the cloning of COMT-related enzymes from other plant sources [24–26] These experiments generated two different frag-ments of 215 bp which were cloned into the pCR2.1-TOPO vector and extended to the full size cDNAs of 1062 and

1074 bp, respectively, by RACE and RLM-RACE (Gen-Bank accession nos AY443006 and AY443008) Prelimin-ary sequence alignments had already revealed a close similarity of the cDNAs with those of other plant OMTs Therefore, the inserts were subcloned into an expression vector for the expression in E coli, and the recombinant polypeptides were extracted from the induced transformants

Fig 2 Thin-layer cochromatography of the labeled product from BMT assays with authentic bergaptol and bergapten on silica F 254 plates developed with n-hexane/ethylacetate/methanol (5 : 5 : 1, v/v/v) Ref-erence furanocoumarins separated in the absence (lane 1) and in the presence of the enzymatic product (lane 3) were spotted by their quenching under irradiation at 254 nm, and the enzymatic product (lanes 2 and 3) was detected by autoradiography using a Bioimager (inverse presentation) S, start line; F, solvent front.

in 70 mM Tris/HCl buffer pH 7.5, containing 10 mM

EDTA The enzyme activity of the crude supernatants

was determined with a variety of potential substrates, and

the 1062 bp transformant was found to methylate bergaptol

to bergapten with narrow substrate specificity The identity

of the enzymatic product was firmly established by

thin-layer cochromatography with authentic bergapten in four

solvent systems (Fig 2), and hence the transformant

encoded a BMT, designated AmBMT The functionality

of the 1074 bp clone encoding a COMT-like protein,

however, has so far not been assigned

Because the RT-PCR from cell culture RNA failed to

amplify a full-size COMT sequence, we turned back to

A majus plants and used the RNA from leaf and stem

tissues as a template These experiments yielded a cDNA of

1095 bp (GenBank accession no AY443007), which was

expressed in E coli and shown to encode a COMT that

converts caffeate to ferulate

Both labeled cDNAs were used as probes for Northern

blotting experiments employing the total RNA of A majus

cells at various time points following the addition of the

Pmg elicitor The abundance of BMT transcripts, which

were hardly detectable in control cells, increased

signifi-cantly to a transient maximum at 7 h (Fig 3) However, a

very weak hybridization signal was recorded for the COMT

transcripts that hardly changes in intensity over the time of

the experiment and corresponded with the low constitutive

level of enzyme activity in the cells

Characterization of enzymes The BMT activity (
2.5 lkatÆkg)1) in the desalted bacterial extracts was very labile and could not be purified exten-sively, whereas the COMT activity (1.6 lkatÆkg)1) remained stable upon storage The enzyme extracts were therefore subjected only to ammonium sulfate fractionation (45–60% saturation for COMT; 60–80% saturation for BMT) and subsequent desalting through PD-10 columns, enhancing the apparent specific activities to 20.2 and 10.3 lkatÆkg)1, respectively, for BMT and COMT The rates of enzyme activity were compared in various buffers in pH range 2.0–10.0 and at temperatures ranging from 20 to 50
C Significant activity of the recombinant BMT was observed between 38
C and 44
C and from pH 6.5–9.0, and the optimum was recorded at 42
C in potassium phosphate buffer pH 8.0, whereas the optimal COMT activity was observed at 32
C in potassium phosphate buffer pH 7.0 These conditions were routinely chosen for all further assays This activity profile of the recombinant BMT was fully compatible with the data measured for BMT extracted from A majus cells (H Ekiert and R Lukacˇin, unpublished data), and the pH dependency corresponded to that of the BMTs from P crispum [22] or R graveolens [34] The effect

of a number of metal ions (Co2+, Cu2+, Fe2+, Fe3+,

Mg2+, Mn2+, Ni2+, Zn2+) at 1.5 mMor 0.1 mM concen-tration was also examined Significant inhibition of the BMT activity was observed in the presence of Cu2+(100%

Fig 3 Induction of BMT transcript abundance

in Ammi majus cell cultures Total RNA (4 lg per dot) isolated from the cells at different time intervals following the addition of elicitor (lanes 1 +, 2 +) or from controls (lanes

3 –, 4 –) treated with water (1 mLÆ40 mL)1 culture) was employed for Northern dot blot hybridization using labeled AmBMT cDNA

as a probe.

Table 1 Substrate specificities of A majus OMTs Substrates were used at 10 m M concentration in the assays Neither of the OMTs accepted umbelliferone, psoralen, xanthotoxol, sinapate, 4-coumarate, 2-coumarate, 3-coumarate, catechol, kaempferol, quercetin, dihydrokaempferol, apigenin or naringenin to a significant extent (< 1%) as a substrate The relative activity values relate to caffeate as the standard substrate.

Substrate

a

K ¼ 2 l bK ¼ 6.5 l

and 51%) and Ni2+(47% and 16%) as well as Co2+(21%

and 10%) COMT activity was completely inhibited at

either of the Cu2+concentrations but less by Ni2+(91.5%

and 47%), Mn2+(83% and 7.5%), or Co2+, Fe3+and

Zn2+(23–30% and 0–5%) Fe2+and Mg2+did not affect

the turnover rates Similar results were reported for

heterologous OMTs [37,38]

A variety of potential substrates, including xanthotoxol

(Table 1), was employed to determine the substrate

specificities of the recombinantly expressed A majus

BMT and COMT However, only bergaptol was accepted

as a substrate by the BMT Kinetic assays revealed the

affinities to S-adenosyl-L-methionine and bergaptol

at Km¼ 6.5 and 2.8 lM, respectively The COMT was much less selective and showed the highest affinity to 5-hydroxyferulate (Km¼ 29 lM) followed by caffeic acid methyl ester, caffeate, esculetin, caffeoyl-CoA, 3-(3,4-dihydroxyphenyl)propionate (dihydrocaffeate) or daphnetin (Table 1)

Relationship of sequences S-Adenosyl-L-methionine-dependent O-methyltransferases are characterized by a common signature of five highly

Fig 4 Alignment of AmBMT and AmCOMT polypeptides from Ammi majus Hyphens were inserted for maximal alignment The consensus sequence (COMTcons) derived from the COMT polypeptides of Ocimum basilicum, Catharanthus roseus, Capsicum annuum, Capsicum chinense, Prunus dulcis and Rosa chinensis is given in the bottom line Identical amino acid residues are denoted by asterisks, and dots mark conservative exchanges The amino acids are numbered in the right margin Highly conserved regions I–V proposed as a signature of S-adenosyl- L -methionine-dependent O-methyltransferases [26,39,40] are underlined, and the motifs 1 and 2 considered to govern the substrate specificity [44,47] are in bold.

conserved regions [39–41], and a corresponding consensus

sequence was assigned from plant OMTs [26] These

elements were also recognized in both the BMT and COMT

sequences from A majus (Fig 4; regions I–V) showing

94.5% and 97% identity with the consensus sequence In

case of rat liver catechol OMT regions I and IV were shown

by X-ray diffraction to be involved in

S-adenosyl-L-methionine and metal binding [42], and the other three

regions are likely to serve the same purpose Generally, five

different structural folds have been reported to bind SAM

during catalysis [43], subclassifying the OMTs, but most

plant OMTs, including COMT and the homologous BMT,

belong to class I In contrast to BMTs, COMTs occur

ubiquituously in plants and have been cloned from many

different sources Based on the COMTs of Ocimum

basilicum, Catharanthus roseus, Capsicum annuum,

Capsi-cum chinense, Prunus dulcis and Rosa chinensis, which share

a sequence identity of about 50% and 72.3% similarity, a

consensus sequence was derived also for the full size

polypeptides (Fig 4) The AmCOMT sequence was fully

compatible with this consensus sequence showing 57%

identity at 80% similarity However, in the light of such a

relationship it is particularly notable that the alignment of

the AmBMT polypeptide with the AmCOMT sequence

revealed 64% identity and 78.4% similarity

Discussion

The activities of XMT and BMT were described previously

from Ruta graveolens [21] and Petroselinum crispum cells

[22] In case of dark-grown Petroselinum cells both activities

were induced upon elicitor treatment to transient maxima at

30–35 h with PcXMT reaching a three- to fourfold higher

value than PcBMT [22], whereas the constitutive BMT

activity of irradiated Ruta cells far exceeded that of XMT

activity [34] The native enzymes purified from induced

parsley cells were reported as stable homodimers of 67 kDa

(XMT) and 73 kDa (BMT) being most active in potassium

phosphate buffer of pH 7.5–8.0 (XMT) or of 8.0–8.5

(B MT) The native enzymes from Ruta appeared to be

larger (85 kDa for BMT and 110 kDa for XMT [34]), and

their stability differed greatly in desalted crude extracts

XMT activity was lost rapidly while the BMT activity

decreased at only a moderate rate [34] In contrast, BMT

from A majus was found to be a rather labile enzyme in

crude extract from plant cells or after recombinant

expres-sion, which did not enable the extensive purification

Furthermore, XMT activity was induced to a negligible

extent in elicited A majus cells as compared to BMT

Nevertheless, the expression of AmBMT in E coli yielded

highly active extracts that revealed a molecular mass

corresponding to that of bovine serum albumin

(67 ± 5 kDa) on size exclusion chromatography calibrated

with alcohol dehydrogenase, bovine serum albumin,

oval-bumin, chymotrypsinogen A and ribonuclease A Apparent

Kmvalues were determined at 2.8 lM(bergaptol) and 6.5 lM

(SAM) which is in accordance with the values reported for

native PcBMT (Km bergaptol4.0 lM; Km SAM3.1 lM) [22]

The cloning of AmBMT revealed a molecular mass of

38.7 kDa for the translated polypeptide, strongly suggesting

a homodimer composition for the native Ammi enzyme as

was shown previously for other OMTs [44–46] The high

degree of homology with heterologous COMTs prompted

us to clone the AmCOMT also, which was achieved using seedlings The alignment for these two OMT polypeptides revealed a surprisingly high degree of homology (Fig 4) The similarity to annotated COMTs had been proposed also for the PcBMT [26], but, unfortunately, the relevant sequence data have not been published and cannot be compared AmBMT and AmCOMT are regulated differ-ently upon elicitation of A majus cells, because the low level

of COMT transcript abundance and activity of the cells hardly changed over the time of the experiments, whereas the AmBMT transcript was transiently induced to a maximum at 7 h More importantly, despite the homology (Fig 4) the substrate specificities of the recombinant OMTs differed greatly The AmBMT exclusively methylated ber-gaptol to bergapten (Fig 1), whereas the AmCOMT accepted several substrates apart from caffeate, with a preference for 5-hydroxyferulate (Table 1)

It is thus obvious that small sequence elements, in addition to the five highly conserved regions required for SAM binding [39,41], strongly affect the substrate specificity

of OMTs AmBMT is a typical member of the COMT family of enzymes which differ from the recently crystallized small-molecule methyl ester OMTs [45] In the case of two crystallized OMTs (chalcone OMT, daidzein 7-OMT) from Medicago sativa, two such regions of 14 (motif I) and 11 amino acids (motif II) were identified and proposed to control the specificity [44] From these and corresponding sequence elements in COMTs and flavonoid OMTs a consensus sequence was established (Fig 4) and used to predict the substrate specificity of a novel OMT [47] In summary, the studies suggested that substitutions of two to three amino acids in motifs I or II may provide a basis for the OMT classification, although a reliable prediction was not possible This is reminiscent of the few amino acid substitutions reported for Clarkia OMTs to discriminate caffeate and (iso)eugenol substrates [48] On comparison of AmCOMT and AmBMT only subtle differences in the motifs I and II were noticed due to five substitutions each (Fig 4), most of which were conservative exchanges However, the mutation of a single residue at other locations might considerably shift the specificity of OMTs for related substrates as has been shown for phenylpropene OMTs from sweet basil [46] Future point mutations will reveal the relevance of these substitutions

Acknowledgements

Financial support by the Deutsche Forschungsgemeinschaft and Fonds der Chemischen Industrie is gratefully acknowledged The authors are indebted to S Specker and S Schreiner for fruitful discussions, to B Rohde for chromatography and to A Batschauer and O Panajotow (Pflanzenphysiologie und Photobiologie, Fachb-ereich Biologie, Universita¨t Marburg) for their part in the subcloning experiments.

References

1 Hamerski, D & Matern, U (1988) Elicitor-induced biosynthesis

of psoralens in Ammi majus L suspensions cultures Microsomal conversion of demethylsuberosin into (+)-marmesin and psora-len Eur J Biochem 171, 369–375.

2 Hamerski, D & Matern, U (1988) Biosynthesis of psoralens.

Psoralen 5-monooxygenase activity from elicitor-treated Ammi

majus cells FEBS Lett 239, 263–265.

3 Tietjen, K.G., Hunkler, D & Matern, U (1983) Differential

response of cultured parsley cells to elicitors from two

non-pathogenic strains of fungi 1 Identification of induced products

as coumarin derivatives Eur J Biochem 131, 401–407.

4 Wendorff, H & Matern, U (1986) Differential response of

cul-tured parsley cells to elicitors from two non-pathogenic strains of

fungi Eur J Biochem 161, 391–398.

5 Hahlbrock, K & Scheel, D (1989) Physiology and molecular

biology of phenylpropanoid metabolism Annu Rev Plant

Phy-siol Mol Biol 40, 347–369.

6 Hahlbrock, K., Scheel, D., Logemann, E., Nu¨rnberger, T.,

Parniske, M., Reinold, S., Sacks, W.R & Schmelzer, E (1995)

Oligopeptide elicitor-mediated defense gene activation in cultured

parsley cells Proc Natl Acad Sci USA 92, 4150–4157.

7 Matern, U (1991) Coumarins and other phenylpropanoid

compounds in the defense response of plant cells Planta Med 57,

15–20.

8 Matern

5 , U & Grimmig, B (1994) Natural phenols as stress

metabolites Natural phenols in plant resistance Acta Hortic.

381, 448–462.

9 Matern, U., Grimmig, B & Kneusel, R.E (1995) Plant cell wall

reinforcement in the disease resistance response: molecular

com-position and regulation C an J Bot 73, 511–517.

10 Nu¨rnberger, T., Nennstiel, D., Jabs, T., Sacks, W.R., Hahlbrock,

K & Scheel, D (1994) High affinity binding of a fungal

oligo-peptide elicitor to parsley plasma membranes triggers multiple

defense responses Cell 78, 449–460.

11 Zangerl, A.R & Berenbaum, M.R (1990) Furanocoumarin

induction in wild parsnip: evidence for an induced defense against

herbivores Ecology 71, 1933–1940.

12 Dercks, W., Trumble, J & Winter, C (1990) Impact of

atmo-spheric pollution alters linear furanocoumarin content in celery.

J Chem Ecol 16, 443–454.

13 Zobel, A.M & Brown, S.A (1990) Seasonal changes of

furanocoumarin concentrations in leaves of Heracleum lanatum.

J Chem Ecol 16, 1623–1634.

14 Pathak, M.A., Parrish, J.A & Fitzpatrick, T.B (1981)

Psoralens in photochemotherapy of skin diseases Farmaco 36,

479–491.

15 Honigsmann, H., Jaschke, E., Gschnait, F., Brenner, W., Fritsch,

P & Wolff, K (1979) 5-Methoxypsoralen (bergapten) in

photo-chemotherapy of psoriasis Br J Dermatol 101, 369–378.

16 Hann, S.K., Cho, M.Y., Im, S & Park, Y.K (1991) Treatment of

vitiligo with oral 5-methoxypsoralen J Dermatol 18, 324–329.

17 Hamerski, D., Beier, R.C., Kneusel, R.E., Matern, U &

Him-melspach, K (1990) Accumulation of coumarins in elicitor-treated

cell suspension cultures of Ammi majus Phytochemistry 29, 1137–

1142.

18 Hamerski, D., Schmitt, D & Matern, U (1990) Induction of two

prenyltransferases for the accumulation of coumarin phytoalexins

in elicitor-treated Ammi majus cell suspension cultures.

Phytochemistry 29, 1131–1135.

19 Murray, R.D.H., Me´ndez, J & B rown, S.A (1982) The Natural

Coumarins: Occurrence, Chemistry and Biochemistry Wiley, New

York.

20 Stanjek, V., Miksch, M., Lu¨er, P., Matern, U & B oland, W.

(1999) Biosynthesis of psoralen: mechanism of a cytochrome P450

catalyzed oxidative bond cleavage Angew Chem Int Ed 38,

400–402.

21 Sharma, S.K., Garrett, J.M & Brown, S.A (1979) Separation of

the S-adenosylmethionine: 5- and 8-hydroxyfuranocoumarin

O-methyltransferases of Ruta graveolens L by general ligand

affinity chromatography Z Naturforsch 34c, 387–391.

22 Hauffe, K.D., Hahlbrock, K & Scheel, D (1986) Elicitor-stimulated furanocoumarin biosynthesis in cultured parsley cells: S-adenosyl- L -methionine: bergaptol and S-adenosyl- L -methio-nine: xanthotoxol O-methyltransferases Z Naturforsch 41c, 228–239.

23 Giuliano, G., Bartley, G.E & Scolino, P.A (1993) Regulation of carotenoid biosynthesis during tomato development Plant Cell 5, 379–387.

24 Frick, S & Kutchan, T.M (1999) Molecular cloning and func-tional expression of O-methyltransferase common to isoquinoline alkaloid and phenylpropanoid biosynthesis Plant J 17, 329–339.

25 Dumas, B., van Doorsselaere, J., Gielen, J., Legrand, M., Fritig, B., van Montagu, M & Inze´, D (1992) Nucleotide sequence of a complementary DNA encoding O-methyltransferase from poplar Plant Physiol 98, 796–797.

26 Ibrahim, R.K., Bruneau, A & Bantignies, B (1998) Plant O-methyltransferases: molecular analysis, common signature and classification Plant Mol Biol 36, 1–10.

27 Sanger, F., Nicklen, S & Coulsen, A.R (1977) DNA sequencing with chain-terminating inhibitors Proc Natl Acad Sci USA 74, 5463–5467.

28 Junghanns, K.T., Kneusel, R.E., Baumert, A., Maier, W., Gro¨ger,

D & Matern, U (1995) Molecular cloning and heterologous expression of acridone synthase from elicited Ruta graveolens

L cell suspension cultures Plant Mol Biol 27, 681–692.

29 Luka cin, R & Britsch, L (1997) Identification of strictly con-served histidine and argenine residues as part of the active site in Petunia hybrida flavanone 3b-hydroxylase Eur J Biochem 249, 748–757.

30 Laemmli, U.K (1970) Cleavage of structural proteins during assembly of the head of bacteriophage T4 Nature 227, 680–685.

31 Lowry, O.H., Roesbrough, N.J., Farr, A.L & Randall, R.J (1951) Protein measurements with the Folin phenol reagent.

J Biol Chem 193, 265–275.

32 Sambrock, J & Russel, D.W (2001) Molecular Cloning: A Laboratory Manual Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY.

33 Hahlbrock, K., Lamb, C.J., Purwin, C., Ebel, J., Fautz, E & Scha¨fer, E (1981) Rapid response of suspension-cultured parsley cells to the elicitor from Phytophthora megasperma var Sojae Plant Physiol 67, 768–773.

34 Thompson, H.J., Sharma, S.K & Brown, S.A (1978) O-Methyl-transferases of furanocoumarin biosynthesis Arch Biochem Biophys 188, 272–281.

35 Maury, S., Geoffroy, P & Legrand, M (1999) Tobacco O-methyltransferases involved in phenylpropanoid metabolism The different caffeoyl-coenzyme A/5-hydroxyferuloyl-Coenzyme A 3/ 5-O-methyltransferase and caffeic acid/5-hydroxyferulic acid 3/5-O-methyltransferase classes have distinct substrate specificities and expression patterns Plant Physiol 121, 215–223.

36 Ebel, J., Hahlbrock, K & Grisebach, H (1972) Purification and properties of an o-dihydricphenol meta-O-methyltransferase from cell suspension culture of parsley and its relation to flavonoid biosynthesis Biochim Biophys Acta 268, 313–326.

37 Sato, F., Tsujita, T., Katagiri, Y., Yoshida, S & Yamada, Y (1994) Purification and characterization of S-adenosyl- L -methio-nine: norcoclaurine 6-O-methyltransferase from cultured Coptis japonica cells Eur J Biochem 225, 125–131.

38 Morishige, T., Tsujita, T., Yamada, Y & Sato, F (2000) Mole-cular characterization of the S-adenosyl- L -methionine: 3¢-hyd-roxy-N-methylcoclaurine 4¢-O-methyltransferase involved in isoquinoline alkaloid biosynthesis in Coptis japonica J Biol Chem 275, 23398–23405.

39 Joshi, C.P & Chiang, V.L (1998) Conserved sequence motifs

in plant S-adenosyl- L -methionine-dependent methyltransferases Plant Mol Biol 37, 663–674.

40 Schluckebier, G., O’Gara, M., Saenger, W & Cheng, X (1995)

Universal catalytic domain structure of AdoMet-dependent

methyltransferases J Mol Biol 247, 16–20.

41 Ibrahim, R.K (1997) Plant O-methyltransferase signatures.

Trends Plant Sci 2, 249–250.

42 Vidgren, J., Svensson, L.A & Liljas, A (1994) Crystal structure of

catechol O-methyltransferase Nature 368, 354–358.

43 Schubert, H.L., Blumenthal, R.M & Cheng, X (2003) Many

paths to methyltransfer: a chronicle of convergence Trends

Bio-chem Sci 28, 329–335.

44 Zubieta, C., He, X.-Z., Dixon, R.A & Noel, J.P (2001) Structures

of two natural product methyltransferases reveal the basis for

substrate specificity in plant O-methyltransferases Nat Struct.

Biol 8, 271–279.

45 Zubieta, C., Ross, J.R., Koscheski, P., Yang, Y., Pichersky, E &

Noel, J.P (2003) Structural basis for substrate recognition in the

salicylic acid carboxyl methyltransferase family Plant Cell 15, 1704–1716.

46 Gang, D.R., Lavid, N., Zubieta, C., Chen, F., B euerle, T., Lewinsohn, E., Noel, J.P & Pichersky, E (2002) Characterization

of phenylpropene O-methyltransferases from sweet basil: facile change of substrate specificity and convergent evolution within a plant O-methyltransferase family Plant Cell 14, 505–519.

47 Schro¨der, G., Wehinger, E & Schro¨der, J (2002) Predicting the substrates of cloned plant O-methyltransferases Phytochemistry

59, 1–8.

48 Wang, J & Pichersky, E (1999) Identification of specific residues involved in substrate discrimination in two plant O-methyl-transferases Arch Biochem Biophys 368, 172–180.