Biochemical Characterization of the Suberization-Associated Anionic Peroxidase of Potato

doi:10.1104/pp.121.1.135

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Biochemical Characterization of the Suberization-Associated Anionic Peroxidase of Potato¹

Mark A. Bernards²^,^*, Warren D. Fleming³, David B. Llewellyn⁴, Ronny Priefer⁴, Xiaolong Yang², Anita Sabatino, and Guy L. Plourde

Program in Chemistry, University of Northern British Columbia, 3333 University Way, Prince George, British Columbia, Canada V2N 4Z9

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
References

The anionic peroxidase associated with the suberization response in potato (Solanum tuberosum L.) tubers during wound healinghas been purified and partially characterized at the biochemicallevel. It is a 45-kD, class III (plant secretory) peroxidase thatis localized to suberizing tissues and shows a preference forferuloyl (o-methoxyphenol)-substituted substrates (order of substratepreference: feruloyl > caffeoyl > p-coumaryl $approx$ syringyl) suchas those that accumulate in tubers during wound healing. Therewas little influence on oxidation by side chain derivatization,although hydroxycinnamates were preferred over the correspondinghydroxycinnamyl alcohols. The substrate specificity pattern isconsistent with the natural substrate incorporation into potatowound suberin. In contrast, the cationic peroxidase(s) inducedin response to wound healing in potato tubers is present in bothsuberizing and nonsuberizing tissues and does not discriminatebetween hydroxycinnamates and hydroxycinnamyl alcohols. A syntheticpolymer prepared using E-[8-¹³C]ferulic acid, H₂O₂, and the purified anionic enzyme containeda significant amount of cross-linking through C-8, albeit withretention of unsaturation.

INTRODUCTION

Top
Abstract
Introduction
Methods
Results
Discussion
References

Suberization is a tissue-specific process whereby cell walls become impregnated with a poly(phenolic) matrix coincident withthe deposition of a poly(aliphatic) matrix between the plasmalemmaand carbohydrate cell wall (for review, see Bernards and Lewis,1998). While the nature of the phenolic matrix remains incompletelydefined, it has recently been shown that in potato (Solanum tuberosumL.) tubers it comprises primarily hydroxycinnamic acids (especiallyno. 3; see Scheme 1 for numbering), and their derivatives(especially no. 3b) (Bernards et al., 1995; Negrel et al.,1996). It has also been shown indirectly that in the suberizedtissues of Quercus suber (Gil et al., 1997) and Clivia miniata(Schreiber, 1996; Zeier and Schreiber, 1997), there is a significantamount of hydroxycinnamic acid (especially nos. 1 and 3)present in the cell walls. These data suggest that the poly(phenolic)component of suberized cell walls is unique and distinct fromcells that are lignified, where the poly(phenolic) matrix comprisesoxidatively cross-linked hydroxycinnamyl alcohols (i.e. the monolignols5a, 6a, and 7a) (Lewis and Yamamoto, 1990).

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Scheme 1. Hydroxycinnamic acid and hydroxycinnamyl alcohol derivatives used as substrates in this study. The aromatic ring substitution pattern is denoted by a number (i.e. hydroxycinnamates 1 $-$ 4 and hydroxycinnamyl alcohols 5 $-$ 7), while derivatives are denoted by lowercase letters. Not every possible derivative was used; refer to Table II for a complete listing of the 25 phenolics used in the substrate specificity study.

The macromolecular assembly process whereby monomeric hydroxycinnamic acids (and/or their derivatives) are transported toand subsequently incorporated (i.e. polymerized) into the carbohydratecell wall matrix remains undefined. By analogy to the oxidativecross-linking model accepted for lignification, it has been hypothesizedthat the phenolic component of suberized cell walls is polymerizedvia a peroxidase/H₂O₂-mediated process (Kolattukudy, 1980). Inthis regard, an anionic peroxidase has been shown to be both temporallyand spatially associated with the wound-induced suberization processin potato tubers (Borchert, 1978; Borchert and Decedue, 1978;Espelie and Kolattukudy, 1985; Espelie et al., 1986).

While the suberin-associated anionic peroxidase has not been fully characterized biochemically, it has been cloned and itsmolecular biology studied. Thus, a cDNA clone of the wound-inducedanionic peroxidase of potato (Roberts et al., 1988; Roberts andKolattukudy, 1989) was used to isolate a genomic clone (containingtwo tandemly oriented anionic peroxidase genes of 96% and 87%homology) from tomato (Lycopersicon esculentum Mill.) (Robertset al., 1988). Expression studies of one of these genes, TAP 1(tomato anionic peroxidase 1), demonstrated both a stress-inducedand a developmentally regulated role for this peroxidase (Mohanand Kolattukudy, 1990; Mohan et al., 1993a, 1993b; Sherf and Kolattukudy,1993). However, with its expression silenced in antisense tomatotransformants, the incorporation of phenolics into the cell wallsof wounded fruits (judged cytochemically by autofluorescence)continued unabated (Sherf et al., 1993). Thus, the suberin-specificrole for the anionic peroxidase of potato and tomato remains tenuous,and more definitive evidence is required to unambiguously assignthis specific function to it.

The specificity with which purified peroxidases oxidize different phenolic substrates (e.g. Converso and Fernandez, 1995;Marquez and Dunford, 1995; Pomar et al., 1997; Loukili et al.,1999), and characterization of the in vitro products formed whenthey are reacted with specific phenolic substrates (e.g. Lewiset al., 1987; Zimmerlin et al., 1994; Wallace and Fry, 1995) mayprovide clues to their in vivo role(s). However, for most peroxidaseisoforms, these properties remain untested. We describe our progressin characterizing the wound-induced anionic peroxidase from potatoat the biochemical level, particularly with respect to some ofits basic biochemical and enzymological properties, includinga major substrate specificity assessment.

	MATERIALS AND METHODS

Top Abstract Introduction Methods Results Discussion References

General

Solvents were of analytical or HPLC grade. Hydroxycinnamic acids (referred to by numbers as given in Scheme 1) 1a,2a, 3a, and 4a, chlorogenic acid 2h,and coniferyl alcohol 6a were purchased from Aldrich. p-Coumaryl5a and sinapyl 7a alcohols were a kind gift of Dr.Norman G. Lewis (Washington State University, Pullman). N-Feruloyloctopamine3f was a kind gift of Dr. Jonathan Negrel (Institut Nationalde la Recherche Agronomique, Dijon, France). All other substrateswere either synthesized according to published protocols or isolatedfrom natural sources (see below). Horseradish peroxidase typeVIII (anionic) was purchased from Sigma.

Plant Material

Potato (Solanum tuberosum cv Russet Burbank) tubers were obtained from Monashee Mountain Seed Potatoes (Lumby, British Columbia,Canada), a member of the British Columbia Seed Potato GrowersAssociation, and propagated in the Prince George, British Columbia,Canada, area. Tubers were harvested each fall and stored at 5°Cin the dark until used. Suberization was induced by slicing surface-sterilizedtubers into 0.5- to 1-cm-thick cross-sectional pieces, and incubatingthem in sterile Magenta boxes as described previously (Bernardsand Lewis, 1992

). For purification of the anionic peroxidase,acetone powders (Espelie and Kolattukudy, 1985

) prepared fromthe mechanically removed suberized layers of 7-d wound-healedtubers were used.

Isoform Analysis

Total soluble protein extracts were prepared separately from 1 g each of suberized and nonsuberized (i.e. the tissue immediatelyunderlying the suberized layer) tissues collected 7 d post wounding,for 30 min on ice in 10 mL of cold extraction buffer (50 mM potassiumphosphate, pH 7.5, containing 300 mM Suc, 20 mM KCl, 10 mM DTT[added fresh at the time of extraction], 3 mM EDTA, and 0.1 mMMgCl₂). After centrifugation at 13,500g, the supernatant was desalted(model P6-DG, Bio-Rad) into 25 mM Bis-Tris-iminodiacetate, pH7.1, and chromatofocused on a Mono-P HR 5/5 column (Pharmacia)over a 7.1 to 3.5 pH range. The pH gradient was generated withbuffer (Polybuffer 74, Pharmacia, pH adjusted to 3.5 with saturatediminodiacetate) at a flow rate of 0.5 mL min¹. Fractions (0.5 mL) were assayed spectrophotometrically usingboth guaiacol/H₂O₂ (20 mM/10 mM; 470 nm) and ferulic acid/H₂O₂(0.15 mM/2 mM; 310 nm).

Purification of Anionic Peroxidase

All purification steps were performed at 4°C or on ice. Column fractions were assayed for peroxidase activity spectrophotometricallyusing 20 mM guaiacol and 20 mM H₂O₂ in acetate buffer (20 mM,pH 5.0) by following the oxidation of guaiacol at 470 nm. Columneluants were monitored at 280 nm.

A total of 100 g of acetone powder (obtained from approximately 530 g of suberized layers) was extracted in 20 separate 5-gbatches. For each batch, proteins were extracted with 40 mL ofcold extraction buffer (50 mM potassium-phosphate, pH 7.5, containing300 mM Suc, 20 mM KCl, 10 mM DTT [added fresh at the time of extraction],3 mM EDTA, and 0.1 mM MgCl₂) on ice for 30 min with occasionalstirring. After squeezing through eight layers of cheesecloth,the extract was centrifuged (10,000g, 20 min, 4°C) and the supernatantwas immediately loaded onto a 2.5- × 28-cm Sephadex G25-M column(Pharmacia) pre-equilibrated with 25 mM Tris-HCl, pH 7.5, andgravity eluted with 25 mM Tris-HCl, pH 7.5, to separate the proteinsfrom low-molecular-mass phenolics present in the extract. Theprotein fraction was collected and brought to 50% saturation withsolid (NH₄)₂SO₄. After centrifugation at 20,000g for 10 min at4°C, the supernatant was brought to 90% saturation with solid(NH₄)₂SO₄ and recentrifuged at 20,000g for 10 min at 4°C). The50% to 90% (NH₄)₂SO₄ pellets were reconstituted in a minimum volumeof 25 mM Tris-HCl, pH 7.5, stored at $-$ 40°C. The 50% to 90% (NH₄)₂SO₄pellets were pooled, desalted into 25 mM Bis-Tris, pH 7.1 (SephadexG25-M, 2.5- × 28-cm), concentrated by ultrafiltration (YM 10 membrane,Amicon, Beverly, MA), loaded onto a 2.5- × 100-cm Sephadex G100column (Pharmacia) pre-equilibrated with 25 mM Bis-Tris, pH 7.1,in five 8- to 10-mL batches, and eluted with 25 mM Bis-Tris, pH7.1, at 0.2 mL min¹.

Fractions from Sephadex G100 containing peroxidase activity were pooled, concentrated to 10 mL by ultrafiltration (YM 10 membrane,Amicon), and loaded onto a 1.5- × 18-cm polybuffer exchanger (PBE)column (Pharmacia) pre-equilibrated with 25 mM Bis-Tris, pH 7.1).Proteins were eluted first with equilibration buffer followedby a pH gradient (7.1 $-$ 3.5) generated with buffer (Polybuffer 74diluted 1:8 with water) at pH 3.5 at 0.5 mL min¹. Fractions containing peroxidase activity were pooled, desalted,and concentrated by ultrafiltration (YM 10 membrane, Amicon) into25 mM Bis-Tris, pH 7.1.

The anionic peroxidase from PBE was loaded onto a 1.0- × 6.5-cm DEAE Sepharose Fast Flow column (Pharmacia) pre-equilibratedwith 25 mM Bis-Tris, pH 7.1, and eluted with a salt gradient (0-300mM NaCl in 25 mM Bis-Tris, pH 7.1, over 60 min) at 1 mL min¹. Fractions containing peroxidase activity were pooled, desalted,and concentrated by ultrafiltration (YM 10 membrane, Amicon) into25 mM Bis-Tris, pH 7.1. The cationic peroxidase from PBE was retainedwithout further purification.

Protein concentrations were estimated by the micro-method modification of the Bradford assay (Bradford, 1976) using commerciallyavailable dye reagent (Bio-Rad) and bovine- $gamma$ -globulins as standards,according to the manufacturer's instructions. The concentrationof pure enzyme was estimated using a molar extinction coefficient( $epsilon$ ₄₀₅) value of 105 mM¹ cm¹.

SDS-PAGE

SDS-PAGE was carried out using 14% acrylamide gels essentially as originally described (Laemmli, 1970

) and modified for theBio-Rad Mini Protean system according to the manufacturer's instructionsbut without boiling. Gels were silver-stained using a modifiedprotocol of de Moreno et al. (1985)

. After successive fixing with20% TCA (minimum 2 h) and MeOH:HOAc:H₂O (4:1:5) (3 × 15 min),gels were rinsed with water (2 × 15 min) and treated with 0.1%AgNO₃ (1 h). After rinsing (2 × 10 s), protein bands were visualizedusing successive washes (3 × 100 mL) with a developer solution(3% [w/v] Na₂CO₃ containing 0.0185% [w/v] formaldehyde). Colordevelopment was stopped using 2.3 M citric acid (7.5 mL/100 mLdeveloper solution).

Gels were internally calibrated using a low-molecular-mass marker kit (Pharmacia) containing phosphorylase B (94 kD), BSA(67 kD), ovalbumin (43 kD), carbonic anhydrase (30 kD), soybeantrypsin inhibitor (20.1 kD), and $alpha$ -lactalbumin (14.1 kD). Peroxidaseactivity was visualized in gels without prior silver-stainingusing guaiacol/H₂O₂ (50 mM each in 50 mM acetate buffer, pH 5),after first rinsing the gels with water (2 × 15 min) to removeSDS. The reaction was stopped by removing the substrates and rinsingthe gels with water.

Calibrated Molecular Sieving Chromatography

A Bio-Prep SE 100/17 column (Bio-Rad, molecular mass range 5-100 kD) was calibrated using thyroglobulin A (670 kD void volumeestimate), IgG (150 kD), BSA (67 kD), ovalbumin (43 kD), carbonicanhydrase (29 kD), myoglobin (17 kD), RNase A (13.7 kD), and vitaminB₁₂ (1.3 kD total volume estimate). Standard solutions (5 mg mL¹) of BSA, carbonic anhydrase, and RNase A were prepared in elutionbuffer (20 mM Tris-HCl, pH 7.5, containing 150 mM KCl). The remainingstandards were part of a calibration kit (Bio-Rad) and were preparedaccording to the manufacturer's instructions. Samples were loadedindividually (100 µL) and eluted with elution buffer at 0.25 mLmin¹. For purified anionic peroxidase, 100 µL of a 5 µM solution inelution buffer was used. Fractions (0.25 mL) were collected andassayed for activity using guaiacol/H₂O₂.

Chemical Deglycosylation

Purified anionic peroxidase (35 µg) was deglycosylated according to the method of O'Donnell et al. (1992)

and analyzed bySDS-PAGE followed by silver staining.

Enzyme Assays

Potato anionic peroxidase, potato cationic peroxidase, and horseradish type VIII (anionic) peroxidase were assayed at a finalconcentration of 0.5 nM. A molar extinction coefficient of 105mM¹ cm¹ was used to adjust their concentrations. For ascorbate and guaiacolsubstrates, the method of Amako et al. (1994)

was used essentiallyas described, except guaiacol was substituted for pyrogallol.For phenolic substrate specificity assays, solutions were preincubatedat 40°C. The following quasi-rapid mixing method, based on thatdescribed by Rasmussen et al. (1995)

, was employed: anionic peroxidase(1 nM) and phenolic substrate (0-0.4 mM), in assay buffer (50mM citrate buffer, pH 4.5 or 6.5, containing 1 mM CaCl₂) was placedin one syringe (3 mL), while H₂O₂ (4 mM) in assay buffer (total3 mL) was placed in another. Equal volumes (1 mL) of each solutionwere mixed by simultaneous injection into a flow cell (75 µL internalvolume) and the initial rate of substrate disappearance was monitoredfor 30 s. Triplicate reactions were measured for each syringefilling and each substrate concentration, with each repeated atleast three times. Slopes (in absorbance units min¹) were measured for the initial, linear phase of the reaction(usually over 5-10 s). The data were fitted to straight linesusing Wolfe-Hanes transformations, and apparent maximum rates(V_max^app) values were extrapolated from intercepts.

Synthesis of Phenolic Substrates

N-(Hydroxycinnamoyl)tyramine derivatives 1b, 2b, 3b, and 4b and the 2-(phenyl)-ethylamine analog3g were synthesized according to the method of Villegasand Brodelius (1990)

. N-(Hydroxycinnamoyl)putrescine derivatives1c and 3c were synthesized according to the methodof Malmberg (1984)

and purified on a 1.5- × 30-cm polyamide column(model SC6, Machery-Nagel, Duren, Germany, pre-equilibrated withwater) eluted with water. Hydroxycinnamyl alcohol-4-O- $beta$ -D-glucosides5b, 6b, and 7b were synthesized via reductionof the corresponding hydroxycinnamoyl-ethyl esters using diisobutylaluminumhydride (Terashima et al., 1995

). Hydroxycinnamate-4-O- $beta$ -D-glucosides1e, 3e, and 4e were synthesized using thesame basic procedure as for 5b, 6b, and 7b,but incorporating ester hydrolysis (10% [w/v] KOH in MeOH for1 h followed by acidification [HCl] and extraction into ethylacetate)in place of the reduction with diisobutylaluminum hydride. Theidentity of each product was verified by NMR spectroscopy (¹H and ¹³C) and comparison with published spectral data.

E-[8-¹³C]Ferulic Acid

Piperidine (50 µL) was added to a suspension of vanillin (97.3 mg, 0.64 mmol) and [2-¹³C]malonic acid (120.2 mg, 1.14 mmol, 1.8 equivalents) in freshlydistilled pyridine (1 mL). The resulting yellow solution was stirredat 55°C for 17 h. The yellow pyridine solution was cooled to roomtemperature, poured into a 6 M solution of HCl (6 mL), and stirredvigorously for 15 min. The aqueous mixture was extracted withEtOAc (4 × 10 mL) and the organic solubles were combined, dried(MgSO₄), concentrated in vacuo, and chromatographed on silicagel (EtOAc:CH₂Cl₂:MeOH, 5:5:1) to produce a yellow solid (94.6mg, 76%). ¹H-NMR (300 MHz, acetone-d₆): $delta$ 3.92 (3H, s, Ar-OMe), 6.38 (1H,dd, J_H7-H8 = 15.9 Hz, J_C7-H8 = 160.8 Hz, H-8), 6.87 (1H, d, J_H5-H6= 8.2 Hz, H-5), 7.14 (1H, dd, J_H2-H6 = 1.8 Hz, J_H5-H6 = 8.2 Hz,H-6), 7.34 (1H, d, J_H2-H6 = 1.8 Hz, H-2), 7.59 (1H, dd, J_H7-H8= 15.9 Hz, J_C7-H7 = 2.7 Hz, H-7), 8.2 (1H, br s, exchangeablewith D₂O, Ar-OH). ¹³C-NMR (75 MHz, acetone-d₆): $delta$ 116.3 (C-8).

Isolation of Phenolic Substrates

The 9-O- $beta$ -D-Glc esters 1d and 3d were isolated from young tomato leaves after first feeding the appropriatehydroxycinnamate precursor (10 mM in water) for 2 to 3 d (Harborneand Corner, 1961

). For sinapoyl Glc 4d, 4-d-old radishseedlings were used. In either case, a total phenolic extractwas prepared (80% aqueous MeOH) from 35 to 100 g fresh weightof plant material, concentrated in vacuo (<40°C) until aqueous,filtered, and applied to a 2.5- × 25-cm polyamide SC6 column (Machery-Nagel)pre-equilibrated with water. The hydroxycinnamoyl glucosides wereeluted from the polyamide column with water and concentrated invacuo (<40°C). Free sugars were precipitated at 4°C by repeatedlyadding (four times) cold MeOH (to 80% [v/v]) to the aqueous fraction,followed by filtration and concentration in vacuo to remove theMeOH. Crude, sugar-free samples were loaded onto a water-equilibrated1.5- × 20-cm Sephadex LH20 column (Pharmacia), and the phenolicglucosides eluted with a stepwise gradient of MeOH (100 mL eachof 0%, 25%, 50%, 75%, and 100% [v/v] MeOH). Fractions containinghydroxycinnamoyl conjugates were selected using their distinctiveUV spectra as a marker. Final purification was achieved usinga semipreparative 25- × 100-mm HPLC C₁₈ column (NovaPak, Waters).Glucosides were eluted with an isocratic gradient (3% [v/v] acetonitrilein water) at 9 mL min¹ and identified on the basis of their ¹H-NMR spectra.

p-Coumaroylglucose 1d

Isolated as an amorphous powder (5 mg). UV (MeOH, $lambda$ _max) 330 nm. ¹H-NMR (300 MHz, MeOH-d₄): $delta$ 3.37-3.46 (4H, m, Glc protons 2 $'$ ,3prime], 4 $'$ , 5 $'$ ), 3.69 (1H, dd, J = 12.0 Hz, 4.8 Hz, H-6 $'$ B), 3.85(1H, dd, J = 1.0 Hz, 12.0 Hz, H-6 $'$ A), 5.57 (1H, d, J_H1-H2= 7.6 Hz, H-1 $'$ ), 6.38 (1H, d, J_H7-H8 = 15.9 Hz, H-8), 6.38 (2H,d, J_H5-H6 = 8.7 Hz, H-3, H-5) 7.49 (2H, d, J_H2-H3 = 8.7 Hz, H-2,H-6), 7.73 (1H, d, J_H7-H8 = 16.0 Hz, H-7).

Feruloylglucose 3d

Isolated as an amorphous powder (38 mg). UV (MeOH, $lambda$ _max) 330 nm. ¹H-NMR (300 MHz, MeOH-d₄): $delta$ 3.31-3.43 (4H, m, Glc protons 2 $'$ ,3 $'$ , 4 $'$ , 5 $'$ ), 3.66 (1H, dd, J = 12.1 Hz, 4.5 Hz, H-6 $'$ B), 3.82 (1H,dd, J = 1.6 Hz, 12.0 Hz, H-6 $'$ A), 3.86 (3H, s, Ar-OMe), 5.54 (1H,d, J_H1-H2 = 7.6 Hz, H-1 $'$ ), 6.38 (1H, d, J_H7-H8 =15.9 Hz, H-8), 6.79 (1H, d, J_H5-H6 = 8.2 Hz, H-5), 7.07 (1H, dd,J _H2-H6 = 1.6 Hz, J_H5-H6 = 8.2 Hz, H-6), 7.18 (1H, d, J_H2-H6 =1.8 Hz, H-2), 7.70 (1H, d, J_H7-H8 = 16.1 Hz, H-7).

Sinapoylglucose 4d

Isolated as pale yellow needles from water (28 mg). UV (MeOH, $lambda$ _max) 330 nm. ¹H-NMR (300 MHz, MeOH-d₄): $delta$ 3.34-3.50 (4H, m, Glc protons 2 $'$ ,3 $'$ , 4 $'$ , 5 $'$ ), 3.70 (1H, dd, J = 8.0 Hz, 4.5 Hz, H-6 $'$ B), 3.84 (1H,d, J = 1.8 Hz, H-6 $'$ A), 3.88 (6H, s, Ar-OMe), 5.59 (1H, d, J_H1-H2= 7.9 Hz, H-1 $'$ ), 6.44 (1H, d, J_H7-H8 = 15.9 Hz, H-8), 6.93 (2H,s, H-2, H-6), 7.72 (1H, d, J_H7-H8 = 15.9 Hz, H-7).

Product Formation

Polymeric products were prepared by the slow addition (0.8 mL h¹) of H₂O₂ (50 mM, 10 mL, in 10 mM phosphate buffer, pH 7) to astirring solution (10 mL, 10 mM phosphate buffer, pH 7) of purepotato anionic peroxidase (0.14 mg) and either ferulic acid 3a(19.4 mg, 0.1 mmol) or E-[8-¹³C]ferulic acid (19.5 mg, 0.1 mmol) in a 40°C water bath. All solutionswere bubbled with N₂ gas prior to use. After 24 h, the reactionmixture was deep red, and the product was precipitated with theaddition of a few drops of concentrated HCl, collected by centrifugation(1250g, 10 min, room temperature), and washed with water (twotimes), collecting the precipitate by centrifugation as above.The final pellet was freeze-dried to yield a dark orange powder,reconstituted in 1 mL of 0.1 M NaOH, loaded onto a 1.5- × 25-cmSephadex G25-M column (Pharmacia) pre-equilibrated with 0.1 MNaOH, and eluted with 0.1 M NaOH at 1.8 mL min¹. The UV-absorbing eluant (A₂₈₀) was collected, acid precipitatedwith HCl, washed with water, and freeze-dried as above to yield10 mg (52%). BSA and ferulic acid were used to estimate the voidand total volumes, respectively, of the column used. For NMR,equal amounts of either natural abundance or ¹³C-enriched reaction product were dissolved separately in 1 mLof 0.1 M KOH in D₂O. A drop of DMSO-d₆ was added as an internalstandard.

	RESULTS

Top Abstract Introduction Methods Results Discussion References

Isoform Analysis

Wounding of potato tubers induced at least three groups of peroxidase isoforms, cationic, neutral, and anionic, in the suberizingtissue isolated from a 7-d-old wound site (Fig. 1). By contrast,the nonsuberized tissue underlying the suberized layer containedpredominantly cationic and neutral forms, with only trace amountsof the anionic forms. All three groups of isoforms oxidized bothferulic acid 3a and guaiacol, albeit with different specificactivity. For example, the cationic isoforms oxidized ferulicacid 3a approximately 1.5 times faster than guaiacol, whilethe anionic form oxidized ferulic acid 3a approximately2.5 times faster than guaiacol. The neutral peroxidase oxidizedboth substrates equally well.

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Figure 1. Isoform analysis of wound-induced peroxidases of potato tubers. Total soluble proteins were extracted from either the (mechanically removed) suberized layer or the unsuberized tissue immediately below the suberized layer of 7-d wound-healed potato tubers, and chromatofocused on a Mono-P HR 5/5 column (Pharmacia). Proteins were loaded at pH 7.1, and the pH gradient (7.1-3.5 over approximately 15 min) started after all of the unbound protein had been washed through (indicated by an arrow). Fractions were assayed separately for activity using both ferulic acid and guaiacol.

Purification of a Wound-Induced Anionic Peroxidase

Potato anionic peroxidase was readily purified to apparent electrophoretic homogeneity (Fig. 2, lane b) from wound-inducedtubers through a combination of size-exclusion and anion-exchangechromatography (Table I). Enzyme activity (using guaiacol asthe substrate) was used as the basis for selection at each step.The final product, representing approximately 20% of the original(i.e. total) activity (measured using ferulic acid as substrate)was recovered in a total yield of 3.5 mg and had a Reinheitszahlvalue (ratio of heme A₄₀₅ to protein A₂₈₀) of 2.7. Typical valuesreported for purified peroxidases range from 1.6 (Kwak et al.,1995

) to 4.1 (Converso and Fernandez, 1995

), with most in the2.6 to 3.3 range (Zimmerlin et al., 1994

; Padiglia et al., 1995

;Rasmussen et al., 1995

). The relatively low pI of the protein(approximately 3.5) and its small size (approximately 45 kD) facilitatedpurification. Remarkably, the enzyme retained its H₂O₂-dependentactivity in the SDS-PAGE gel (Fig. 2, lane d), confirming thatthe isolated protein was a peroxidase.

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Figure 2. SDS-PAGE analysis of purified anionic peroxidase from potato electrophoresed in a 14% acrylamide gel under denaturing conditions, before (lane b) and after (lane c) treatment with TFMS. Lane a, Molecular mass markers, including BSA (67 kD), ovalbumin (43 kD), carbonic anhydrase (30 kD), soybean trypsin inhibitor (20.1 kD), and $alpha$ -lactalbumin (14.1 kD). Lane d, Activity stain using guaiacol/H₂O₂. Proteins in lanes a to c were visualized by silver staining. After staining, gels were dried onto cellulose acetate sheets (Bio-Rad) and scanned to generate digital images.

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Table I. Purification summary for the anionic peroxidase isolated from potato tubers during wound healing

Anionic peroxidase was purified from potato tubers 7 d after wounding.

Potato Anionic Peroxidase Characterization

The purified potato anionic peroxidase has a molecular mass of 45.8 kD, based on SDS-PAGE (Fig. 2, lane b). Deglycosylationwith trifluoromethane sulfonic acid (TFMS) yielded a 35.3-kD protein(Fig. 2, lane c). Calibrated molecular-sieving chromatographypredicted a molecular mass of 44.9 kD for the purified protein(data not shown). The enzyme displayed a broad temperature optimumbetween 40°C and 60°C (data not shown) and a pH optimum of 4.5for phenolic acids and 6.5 for monolignols (Fig. 3). In both cases,the pH optima were broad, and neutral conjugates (e.g. 3b)were equally good substrates at either pH (data not shown). Forconvenience, all substrates except the hydroxycinnamyl alcohols(5a, 5b, 6a, 6b, 7a, and 7b)were assayed at pH 4.5.

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Figure 3. Dependence of phenolic oxidation rate by potato anionic peroxidase on pH. The rate of oxidation of ferulic acid 3a (black symbols) and coniferyl alcohol 6a (white symbols) was measured spectrophotometrically in buffers of differing pH. The buffers used (all at 50 mM) were citrate ( $bullet$ ), acetate ( $black-square$ , $square$ ), His ( $black-triangle$ , $triangle$ ), phosphate ( $down-triangle$ ), and Tris ( $diamond$ ). Oxidation rates were measured in triplicate. Error bars represent ±1 SD.

Substrate Specificity of Potato Peroxidases

Anionic Peroxidase

Twenty-five different phenolic compounds were tested as substrates (Table II; Scheme 1). The potato anionic peroxidase showeda strong preference for substrates with o-methoxyphenol-substitutedaromatic ring systems. Thus the hydroxycinnamates 3a, 3b,3c, 3d, 3f, and 3g were all excellentsubstrates, while (in decreasing order) the caffeoyl (2a,2b, and 2h), p-coumaroyl (1a-1d),and sinapoyl (4a-4d) compounds were less effective.The hydroxycinnamyl alcohols (5a, 6a, and 7a)were poorer substrates than the corresponding hydroxycinnamates,but still showed the same pattern of maximal activity with theo-methoxyphenol-substituted coniferyl alcohol 6a. As expected,protection of the phenolic hydroxyl groups (i.e. the initial siteof oxidation by peroxidase) with Glc moieties (e.g. 1e,3e, 4e, 5b, 6b, and 7b) preventedtheir oxidation by the enzyme. The potato anionic peroxidase readilyoxidized guaiacol, both in the presence and absence of p-chloromercuribenzoicacid (pCMB) (up to 200 µM), while ascorbate was a very poor substrate(data not shown).

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Table II. Substrate specificity of potato anionic peroxidase

Maximum catalytic rates were determined for each substrate by measuring the initial rate of their consumption over a range of concentrations (0-0.2 mM) with a fixed concentration of H₂O₂ (2 mM). The rate values were predicted from the intercepts of Wolfe-Hanes plots. For all assays, the purified potato anionic peroxidase was used at a 0.5 nM final concentration.

Cationic Peroxidase

A subset of the phenolics tested as substrates for the anionic peroxidase, including the hydroxycinnamates 1a, 2a,3a, and 4a and coniferyl alcohol 6a, werealso tested with the partially purified cationic peroxidase(s)of potato (Table III; Scheme 1). In contrast to the specificityapparent for the anionic peroxidase, the cationic peroxidase(s)oxidized ferulic acid 3a and coniferyl alcohol 6aequally well. A similar trend in preference for aromatic substitutionpatterns was observed. The (descending) order of substrate preferencefor the cationic isoform(s) was feruloyl > caffeoyl > syringyl> p-coumaryl.

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Table III. Substrate specificity for selected peroxidase isoforms

Values represent relative rates of oxidation of the substrates listed, with ferulic acids arbitrarily set to 100%. Isoforms are grouped as either cationic or anionic.

Potato Anionic Peroxidase Reaction Products

The acid-insoluble product(s) obtained from the slow addition of H₂O₂ to an enzyme/ferulic acid solution appeared to be polymeric(M_r > 5,000), on the basis of its elution in the void volume ofa Sephadex G25-M column (Fig. 4). The natural abundance polymerhad only a single weak resonance in its ¹³C-NMR spectrum, corresponding to the methoxyl carbon ( $delta$ 56.8 ppm),owing to the heterogeneous nature of the polymer as well as thelow abundance of sample (data not shown). In the ¹³C-NMR spectrum obtained for the polymer prepared from E-[8-¹³C]ferulic acid (Fig. 5), however, major resonances wereapparentat $delta$ 171.8, 124.2, 122.9, 118.0, 105.4, and 59.6 ppm, with minorresonances observed at $delta$ 136.3, 135.3, 130.4, and 55.3 ppm.

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Figure 4. M_r characterization of the polymeric product prepared by the incubation of ferulic acid/H₂O₂ with purified anionic peroxidase. The acid-insoluble precipitate collected after incubation of anionic peroxidase with ferulic acid/H₂O₂ was dissolved in 0.1 M NaOH and eluted from a Sephadex G25-M column. BSA was used to mark the void volume of the column. The ferulic acid monomer was used to mark the total volume of the column.

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Figure 5. Solution-state ¹³C-NMR spectroscopic analysis of the polymeric product prepared by the incubation of E-[8-¹³C]ferulic acid/H₂O₂ with purified anionic peroxidase. Ten milligrams of the polymeric product collected from a Sephadex G25-M column was dissolved in 0.1 M KOH prepared in deuterated water. A drop of DMSO was added as an internal standard. With the exception of the resonance at 56.79 ppm, all resonances are due to the enhanced C-8 of the initial substrate.

	DISCUSSION

Top Abstract Introduction Methods Results Discussion References

The Anionic Potato Peroxidase and Suberization

Wounding of potato tubers results in a gradual increase in total soluble peroxidase activity over a period of 5 to 7 d (Borchert,1978

; Roberts et al., 1988

). This involves the synthesis of newprotein and is preceded by the accumulation of mRNA (Roberts etal., 1988

). However, plants typically contain multiple peroxidaseisoforms and it is not surprising that several (i.e. cationic,neutral, and anionic) are induced in potato under wound healingconditions (Borchert, 1978

; Borchert and Decedue, 1978

; Fig. 1),with the cationic and anionic forms predominating. Since suberizationis restricted to the two to three cell layers immediately belowthe wound site (Borchert, 1978

; Borchert and Decedue, 1978

; Kolattukudy,1980

), and the anionic isoform(s) is immunocytochemically (Espelieet al., 1986

) and biochemically (Fig. 1) localized to this region,it is strongly implicated in the suberization process.

Potato Anionic Peroxidase Characterization

Heme peroxidases are classified as either class I (intracellular), class II (fungal secretory), or class III (plant secretory),largely based on their structure (i.e. carbohydrate content, numberof bound Ca²⁺ atoms, number of disulfide bridges, etc.) (Welinder, 1985

; O'Donnellet al., 1992

), substrate preference (i.e. ascorbate versus guaiacol),and sensitivity to pCMB (Amako et al., 1994

). For example, classI intracellular peroxidases, typified by ascorbate peroxidase,prefer ascorbate as substrate and are inhibited by pCMB, whileclass III peroxidases (the so-called guaiacol or secretory peroxidases)prefer guaiacol as substrate and show no sensitivity to pCMB (Amakoet al., 1994

). For potato anionic peroxidase, the large (10.7kD) shift in molecular mass after treatment with TFMS, its preferencefor guaiacol over ascorbate as substrate, and its insensitivityto pCMB clearly distinguish it as a class III peroxidase.

In the present study, we found that the highly anionic peroxidase from potato had a molecular mass of approximately 45 kD,as determined by both SDS-PAGE and calibrated molecular-sievingchromatography. While this molecular mass is consistent with thatreported earlier (Espelie and Kolattukudy, 1985), and with thatfor other anionicperoxidases of solanaceous species (e.g. Pomaret al., 1997), it is not consistent with that predicted by thepublished amino acid sequence (Roberts et al., 1988). Since thelatter was deduced from a cDNA showing three possible start sites,it could not be used with confidence to predict the molecularmass of the native protein. Instead, as a tightly folded, globularprotein, its elution from a molecular-sieving column can be takenas a good first approximation. In this case, both the SDS-PAGE(45.8 kD) and molecular-sieving chromatography (44.9 kD) predictionswere in close agreement. While the influence of the carbohydrateside chains on sieving behavior cannot be discounted, the deglycosylatedprotein still had a molecular mass approximately 6 kD greaterthan that predicted (Roberts et al., 1988) for the unglycosylatedprotein.

Substrate Specificity

The reaction catalyzed by peroxidase is both complex (Scheme 2) and fast, and does not follow simple Michaelis-Menten kinetics(e.g. Nakajima et al., 1991

). The initial step involves the bindingof H₂O₂ by the Fe(III) heme, followed by its oxidation, cleavageof the O-O bond, and the subsequent formation of a ferryl (Fe[IV]=O)-porphorin $pi$ -cation radical (referred to as compound I), accompanied by therelease of water. Next, the first of two reducing substrates (e.g.R-OH in Scheme 2) binds and donates one electron to compound I,reducing the porphorin cation and resulting in a ferryl (Fe[IV]=O)enzyme (referred to as compound II). The reducing substrate isreleased as a radical (e.g. R-O^· in Scheme 2). In the last step of the cycle, a second reducingsubstrate binds and donates an electron to Fe(IV)=O, resultingin the reduction of the heme to Fe(III) and, with the additionof two protons, the release of water. A second radical is generatedin the process. Thus, the stoichiometry of the reaction involves2 mol phenolic substrate oxidized for each mole of H₂O₂ reduced,with different binding affinities for the phenolics for compoundsI and II.

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Scheme 2. General reaction mechanism for peroxidase. See text for detailed description of each step. R-OH, Phenolic substrate; R-O^·, phenolic radical.

Coupled with the apparent inhibition observed when the concentration of H₂O₂ is disproportionately large, simple Michaelis-Mentenconstant determinations become increasingly difficult. While itis possible to measure rate constants for the individual reactionsshown in Scheme 2 (Rasmussen et al., 1995; Converso and Fernandes,1996; Rodriguez-Lopez et al., 1996), it requires special rapidkinetics equipment. Therefore, in determining the substrate preferenceof the potato anionic peroxidase, we have employed a relativelysimple, quasi-rapid mixing spectrophotometric assay in which theinitial rate of phenolic substrate depletion was used as an indicatorof relative activity under conditions of saturating H₂O₂ (i.e.saturation or steady-state kinetics). Rapid mixing is essentialto monitor the reaction, since the initial rate is only linearfor about 5 to 10 s (depending on substrate concentration). Ourprocedure allowed monitoring within 1 to 2 s of mixing. Underthe conditions used, the rate of ferulic acid oxidation was linearwith respect to enzyme concentration (data not shown), indicatingthat the reaction was being monitored at saturating concentrations.For most substrates, saturation kinetics were observed, but forothers (especially 1e, 3e, 4e, 5a,5b, 6b, 7a, and 7b) saturation wasnot achieved. For these compounds, oxidation rates were very lowrelative to ferulic acid 3a (Table II), and the maximumrate observed is reported.

The reduction of compound II (step 3 in Scheme 2) is rate limiting when there is sufficient H₂O₂ present (Rodriguez-Lopezet al., 1996); however, there are substantial differences in therate of compound II formation (step 2 in Scheme 2) depending onthe reducing substrate (Takahama, 1995; Takahama et al., 1996).For example, the rate of sinapic acid 4a oxidation by horseradishperoxidase isoforms can be greatly enhanced by the addition ofsmall amounts of either p-coumaric 1a or ferulic 3aacids to the reaction mixture (Takahama, 1995), presumably becausethe latter (especially 3a) react to form compound II morereadily than sinapic 4a acid alone. Consequently, the "rates"shown in Table II reflect the relative efficiency with which theenzyme can use each substrate for its complete catalytic cycle.

The substrates used were selected because many (i.e. 2c, 2h, 3b, 3c, and 3f) are knownto accumulate in potato tubers during would healing (e.g. Malmberg,1984; Bernards and Lewis, 1992; Borg-Olivier and Monties, 1993;Negrel et al., 1996), and are potential "natural" substrates forthe enzyme. Other compounds (e.g. the hydroxycinnamoyl-9-O- $beta$ -D-glucosides1d, 3d, and 4d) are common in solanaceousplants (Harborne and Corner, 1961). The monolignols 5 to 7 werealso included since they are known to be incorporated into suberizingcell walls, albeit in minute amounts (Borg-Olivier and Monties,1989, 1993). The remaining substrates represent the free acids,analogs, and/or modifications of the "natural" substrates. Forexample, N-feruloyl-(2-phenyl)-ethylamine 3g representsa dehydro analog of N-feruloyltyramine 3b.

The highest rate of enzyme activity was measured with feruloyl derivatives as substrate (Table II). Indeed, the enzyme seemsparticularly sensitive to the aromatic substitution pattern ofits substrates, and showed a marked preference for those thatare o-methoxyphenol substituted. The (descending) order of substratepreference is feruloyl > caffeoyl > p-coumaryl $approx$ syringyl, withlittle influence by side chain derivatization. Coincidentally,the major compounds accumulating in potato tubers induced to suberizevia wounding (with the exception of chlorogenic acid 2h)are ferulic acid derivatives, and their ready oxidation by thepotato anionic peroxidase implicates them (and the enzyme) inthe suberization process. Interestingly, the oxidation of N-feruloyl-(2-phenyl)-ethylamine3g was more rapid than that of N-feruloyltyramine 3b,indicating that the enzyme discriminates between the hydroxycinnamateand tyramine ends of the substrate.

In order to place the substrate specificity of the potato anionic peroxidase in context, we measured the relative oxidationof the hydroxycinnamic acids 1a, 2a, 3a,and 4a, as well as coniferyl alcohol 6a by a partiallypurified cationic peroxidase preparation from wounded potato tubers,as well as a commercially available anionic horseradish peroxidase(Table III). In addition, literature data for nine other peroxidaseisoforms for which comparative data are available are included.(Note that the literature contains many reports in which onlyone hydroxycinnamate substrate was used, usually ferulic acid3a, but these do not provide comparative values and arenot considered here.) Whereas most isoforms show a similar preferencefor o-methoxyphenol substituted substrates (i.e. ferulic acid3a), some differences are apparent. For example, the descendingorder of substrate preference for the anionic horseradish peroxidaseisoforms VII and VIII is feruloyl > caffeoyl > p-coumaroyl > syringyl,while that for the cationic isoform IX is p-coumaryl > feruloyl> syringyl (Takahama, 1995).

The two cationic peroxidases from Vaccinium myrtillus also preferentially oxidize ferulic acid 3a over other hydroxycinnamicacids, although they differ in their ability to oxidize p-coumaricacid 1a (Melo et al., 1997). In contrast, three soybeanperoxidase isoforms (two cationic and one anionic) more readilyoxidized caffeic acid 2a than ferulic acid 3a, whiletwo others (both anionic) were unable to oxidize caffeic acid2a at all (Schmitz et al., 1997). In general, the cationicperoxidases listed in Table III oxidized coniferyl alcohol 6aequally well or better than ferulic acid 3a, while anionicones more readily oxidized ferulic acid 3a. For the wound-inducedanionic peroxidase of potato, all hydroxycinnamates appeared tobe more readily oxidized than their corresponding hydroxycinnamylalcohols (Table II). Thus, of the peroxidase isoforms inducedupon wounding of potato tubers, the anionic one appears predisposedto favor oxidation of the major phenolic compounds that accumulatecoincidentally. Since some of these (especially 3c) becomeoxidatively cross-linked in the suberized cell walls of tubers,the anionic peroxidase is implicated in the process.

Product Analysis

Horseradish peroxidase has often been used to generate dehydrogenation polymers of coniferyl alcohol (e.g. Lewis et al., 1987

;Lewis and Yamamoto, 1990

). The type of product obtained dependson the rate at which the substrates (i.e. coniferyl alcohol andH₂O₂) are added to the enzyme (see Saake et al., 1996

; Guan etal., 1997

). In the present study, the slow addition of H₂O₂ toa stirring solution of purified anionic peroxidase and ferulicacid 3a yielded a polymer of M_r > 5,000, as judged by chromatographyon a Sephadex G25-M column (Fig. 4). More than half (i.e. 52%)of the original monomer was recovered in this polymeric fraction.Based on a monomer molecular mass of approximately 194 g mol¹, the recovered material represents a polymer with a minimal degreeof polymerization of 26. By contrast, either the rapid additionof H₂O₂ or the addition of both substrates at once to a stirringsolution of purified anionic peroxidase yielded mainly low-M_r,acid-soluble products, not unlike those reported by Zimmerlinet al. (1994)

(data not shown).

NMR spectroscopic analysis (Fig. 5) revealed two important features of the in vitro polymeric product(s) formed by the slowaddition of H₂O₂ to a stirring solution of E-[8-¹³C]ferulic acid and the purified enzyme. First, only a small proportionof the total enhanced resonances (approximately 30%) correspondto that of the original E-[8-¹³C]ferulic acid (i.e. $delta$ 118.0 ppm), indicating that the majorityof carbons originating from C-8 of the monomer were found in amodified electronic environment, including their involvement incross-linking. Second, the majority of resonances were found inthe olefinic region of the spectrum (i.e. $delta$ 110-150 ppm), indicatingthat C-8 of the original monomer retains its unsaturation, despitebeing cross-linked with other monomeric units. This feature ofin vitro peroxidase/H₂O₂-generated polymers represents a deviationfrom polymers generated using horseradish peroxidase and monolignols(e.g. Lewis et al., 1987; Guan et al., 1997), where the side chaincarbons were reduced during coupling. It is consistent, however,with the retention of side chain unsaturation noted when [2-¹³C]Phe was administered to suberizing potato tubers (Bernards etal., 1995). Recently, Ralph et al. (1994) described a number offerulic acid dehydrodimers present in grass cell walls, some ofwhich show carbon resonances consistent with those observed inthe polymeric product generated by the anionic peroxidase. Curiously,the enhanced signal at 171.8 ppm (Fig. 5) suggests that a minorproportion of the ferulic acid monomers underwent oxidation atC-8 to a carbonyl during the reaction with anionic peroxidase.Notwithstanding this interpretation, the analysis of the polymersgenerated in vitro by the anionic peroxidase of potato requiresfurther study.

	CONCLUSIONS

The macromolecular assembly of the aromatic domain in suberized tissues is hypothesized to involve a peroxidase/H₂O₂-mediatedfree radical coupling process. One candidate peroxidase in potatotubers is the highly anionic isoform that is induced by wounding.The biochemical evidence presented here supports this contentionon two counts. First, the anionic peroxidase is restricted tothe suberizing tissues in the immediate vicinity of the woundsite. Second, the anionic peroxidase of potato prefers o-methoxyphenol-substitutedhydroxycinnamates (typical of those that accumulate in tubersduring wound healing and incorporated into the suberized cellwall) to other phenolic substrates (order of substrate preference:guaiacyl > caffeoyl > p-coumaryl $approx$ syringyl) including hydroxycinnamylalcohols. This contrasts with the cationic peroxidase(s) of potato,which is found in the tissues underlying the wound site (in additionto the suberizing tissues), and does not discriminate betweenferulic acid 3a and coniferyl alcohol 6a. The purifiedanionic enzyme readily formed dehydrogenative polymers from ferulicacid 3a in the presence of H₂O₂ that are characterizedby a high level of cross-linking (potentially through side chainC-8) and a high degree of retention of side chain unsaturation.In general, the data presented in this paper are consistent withthe involvement of the anionic peroxidase isoform of potato inthe polymerization of the poly(aromatic) domain during suberization,although definitive proof awaits further investigation.

	FOOTNOTES

¹   This research was supported by a Natural Sciences and Engineering Research Council of Canada (NSERC) operating grant to M.A.B.D.B.L. was supported in part by a NSERC undergraduate scholarship.
²   Present address: Department of Plant Sciences, University of Western Ontario, London, ON, Canada N6A 5B7.
³   Present address: Department of Biology, University of Alberta, Edmonton, AB, Canada T6G 2E9.
⁴   Present address: Department of Chemistry, McGill University, Montreal, PQ, Canada H3A 1B1.
^*   Corresponding author; e-mail bernards{at}julian.uwo.ca; fax 519-661-3935.

Received January 12, 1999; accepted May 22, 1999.

ACKNOWLEDGMENT

The authors gratefully acknowledge the assistance of Dr. David Dick (University of Northern British Columbia) in acquiringNMR spectra.

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Biochemical Characterization of the Suberization-Associated Anionic Peroxidase of Potato1

Biochemical Characterization of the Suberization-Associated Anionic Peroxidase of Potato¹