Generation of Polyclonal Antibodies of Predetermined Specificity against Pediocin PA-1

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Applied and Environmental Microbiology, November 1998, p. 4536-4545, Vol. 64, No. 11
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Generation of Polyclonal Antibodies of Predetermined Specificity against Pediocin PA-1

José M. Martínez, María I. Martínez, Ana M. Suárez, Carmen Herranz, Pilar Casaus, Luis M. Cintas, Juan M. Rodríguez, and Pablo E. Hernández^*

Departamento de Nutrición y Bromatología III, Facultad de Veterinaria, Universidad Complutense, 28040 Madrid, Spain

Received 21 January 1998/Accepted 13 August 1998

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

Polyclonal antibodies of predetermined specificity for pediocin PA-1 (pedA1) have been generated by immunization of rabbitswith a chemically synthesized C-terminal fragment of this bacteriocin(PH2) conjugated to the carrier protein keyhole limpet hemocyanin(KLH). The sensitivity and specificity of the PH2-KLH-generatedantibodies were evaluated by the development of various enzyme-linkedimmunosorbent assays (ELISAs) $---$ a noncompetitive indirect ELISA(NCI-ELISA), a competitive indirect ELISA (CI-ELISA), and a competitivedirect ELISA (CD-ELISA) $---$ and by immunodotting. All immunoassaysindicated the existence of pedA1-specific antibodies with highrelative affinities and adequate sensitivities in the sera ofimmunized animals. The limits of detection of pedA1 in MRS medium(Oxoid Ltd., Basingstoke, United Kingdom) were found to be 2.5µg/ml by immunodotting and 1 µg/ml in the NCI-ELISA. However,the CI-ELISA enhanced the limit of detection of pedA1 to 0.025µg/ml, while the amount of free pedA1 required for 50% bindinginhibition was 10 µg/ml. Moreover, the CD-ELISA increased theaffinity of the PH2-KLH-generated antibodies for pedA1; the limitof detection of pedA1 was less than 0.025 µg/ml, and the 50% bindinginhibition value was reduced to 0.5 µg of pedA1/ml. All immunoassaysand the slot dot assay detected the presence of pedA1 in the supernatantof the producing strain Pediococcus acidilactici 347, with noreactivity or negligible immunoreactivity with the supernatantsof other lactic acid bacteria producing or not producing differentbacteriocins. The approaches taken for the generation of antibodiesand the development of immunoassays could prove useful for thegeneration and evaluation of antibodies of predetermined specificityfor other bacteriocins of interest in the foodindustry.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

Many bacteriocins from gram-positive bacteria have fairly broad inhibitory spectra, and these bacteriocins may have appliedpotential as antimicrobial agents. In particular, many lacticacid bacteria (LAB) produce bacteriocins that have become attractiveas natural food preservatives (26, 30, 31). The LAB bacteriocinsdescribed to date share a number of common traits which justifytheir classification in three well-defined classes (36, 41).Pediocin PA-1 belongs to the pediocin family of bacteriocins,a class of small, heat-stable, non-lanthionine-containing, membrane-activepeptides that have a YGNGVxC consensus motif and that are inhibitoryfor a broad spectrum of gram-positive bacteria, including spoilageand food-borne pathogens (2, 10). Pediocin PA-1 producedby Pediococcus acidilactici is identical to pediocin AcH (39),and it has been characterized at the biochemical (27, 42)and genetic (38, 57) levels. Pediocin PA-1 is a 44-amino-acidpeptide that has a molecular mass of 4,629 Da and that containsfour cysteine residues which participate in the formation of twodisulfide bridges in the mature bacteriocin. The peptide is predictedto exist largely as a random coil, with only a small hydrophobicregion in residues 21 to 25 with a propensity to form a $beta$ sheet(36). This bacteriocin has also been expressed in heterologoushosts (11, 38), and it is a promising antimicrobial agentfor use in the foodindustry.

The development of efficient detection and purification procedures for pediocin PA-1 and other bacteriocins could greatlyfacilitate their use as food preservatives (37). The generationof antibodies against bacteriocins may provide specific and sensitivemethods for the isolation and detection of producing strains andfor the quantification of bacteriocins in different substratesby use of immunochemical assays. Antibodies also offer potentialalternative methods for the purification of bacteriocins by useof immunoaffinity chromatography strategies (50). However, reportson the generation of antibodies against bacteriocins have beenscarce and have been based on the use as the immunogen of wholebacteriocin molecules, either alone or conjugated to carriers(5, 6, 18, 49, 51). Moreover, many bacteriocins, eitherlantibiotic or nonlantibiotic, share common amino acid residues(2, 10, 36, 41), and the use as an immunogen of wholebacteriocin molecules might generate antibodies cross-reactivewith common consensus amino acid sequences. These antibodies thereforewould not be unique and specific for the bacteriocin against whichthey weregenerated.

The use of chemically synthesized fragments deduced from the amino acid sequence of the bacteriocin of interest could facilitateobtaining antibodies of predetermined specificity for the sensitiveand specific recognition of the native bacteriocin molecule. Antipeptideantibodies have become important tools in many research fieldsfor identifying gene products, for analyzing the functional domainsof enzymes, for evaluating the potential efficacy of syntheticpeptide vaccines, for protein purification, and for assaying analytesin immunochemical assays (32, 52, 56). We report in thiscommunication the generation of specific rabbit polyclonal antibodiesagainst a chemically synthesized C-terminal fragment of the bacteriocinpediocin PA-1 and the development of sensitive immunoassays forpediocin PA-1 analysis. The approaches taken for selection ofthe peptide fragment and carrier molecule, conjugation methods,and immunoassay development could prove useful for the generationand evaluation of antibodies of predetermined specificity forother bacteriocins of interest in the foodindustry.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Materials. The amino acid sequence of the C-terminal fragment of pediocin PA-1 (peptide PH2) used in this work was NH₂-ATGGHQGNHKC-COOH.Peptide PH2 (residues 34 to 44, 1,109 Da, 20 mg) was synthesizedby 9-fluorenylmethoxycarbonyl chemistry with an Applied Biosystems431A automated solid-phase peptide synthesizer in the ProteinChemistry Facility at the Centro de Biología Molecular SeveroOchoa (Madrid, Spain) under the direction of J. Vázquez. Thepurity of the peptide was monitored by reverse phase (RP) high-pressureliquid chromatography and was found to be higher than 95%, andthe peptide identity was confirmed by mass spectrometry. A chemicallysynthesized fragment corresponding to the N-terminal region ofpediocin PA-1 (PH1) was used as a control. The amino acid sequenceof peptide PH1 (residues 1 to 9, 1,004 Da, 10 mg) was NH₂-KYYGNGVTC-COOH.Peptide PH1 was synthesized and purified as described for peptidePH2. Ovalbumin (OA) (grade III and fraction VII), horseradishperoxidase (HRP) (fraction VI), Tween 20, glutaraldehyde, andFreund's adjuvants were obtained from Sigma Chemical Co., St.Louis, Mo. The Imject activated-immunogen conjugation kit containingmaleimide-activated keyhole limpet hemocyanin (KLH), maleimide-activatedOA, conjugation buffer, and gel filtration columns was obtainedfrom Pierce Chemical Co., Rockford, Ill. Goat anti-rabbit immunoglobulinG (IgG) conjugated to HRP was obtained from Cappel Laboratories,West Chester, Pa. Pure nisin A (30,000 U/mg) was purchased fromNBS Biologicals (Hartfield, United Kingdom). Rabbits (New ZealandWhite females) were purchased from a local supplier (Navarra,Spain).

Preparation of immunoconjugates and immunization. PH2 was conjugated to maleimide-activated KLH (PH2-KLH, 1:2, wt/wt) by use of the components of the Imject activated-immunogenconjugation kit for use as the immunogen. Peptide PH2 was alsoconjugated to maleimide-activated OA (PH2-OAM, 12.5:1, mol/mol)and to OA by the glutaraldehyde method (PH2-OAG, 12:1, mol/mol)(1, 7) for use as solid-phase antigens. Peptide PH1 wasconjugated to OA by the glutaraldehyde method (PH1-OAG, 12.5:1,mol/mol) for use as a solid-phase antigen. PH2 and purified pediocinPA-1 were also conjugated to HRP (PH2-HRP, 1:5, wt/wt, and pedA1-HRP,1:5, wt/wt, respectively) by the periodate method (40) for usein one of the enzyme-linked immunosorbent assays (ELISAs) (competitivedirect ELISA [CD-ELISA]).

Rabbits were immunized with PH2-KLH in accordance with the following scheme: (i) 450 µg in complete Freund's adjuvant (1:1)intradermally on day 0, (ii) the same concentration of the immunogenin incomplete Freund's adjuvant (1:1) intramuscularly on days14 and 21, (iii) the same concentration of the immunogen in incompleteFreund's adjuvant intradermally on day 35, and (iv) two more dosesof the immunogen in incomplete Freund's adjuvant on days 45 and56. Rabbits were bled via marginal ear veins on days 28 and 63,and a final bleed was performed on day 72 by cardiac puncture.Serum was obtained after overnight incubation of blood at 4°Cand centrifugation at 1,000 × g for 15min.

ELISAs. For antiserum titration, flat-bottom polystyrene microtiter plates (Maxisorp; Nunc, Roskilde, Denmark) were coated overnight(4°C) with 100 µl of PH2-OAG (5 µg/ml) in 0.1 M sodium carbonate-bicarbonatebuffer (pH 9.6) (coating buffer [CB]). The plates were washedthree times with 300 µl of washing solution (0.05% Tween 20 inphosphate-buffered saline [0.01 M, pH 7.4] [PBS]). The plateswere blocked for 30 min at 37°C with 300 µl of 1% (wt/vol) OA(grade III) in PBS (OA-PBS) and then were washed six times. Next,50 µl of serially diluted serum was added to each well and incubatedfor 1 h at 37°C. Unbound antibody was removed by washing fourtimes, and 100 µl of goat anti-rabbit IgG-peroxidase conjugate(diluted 1:500 in OA-PBS) was added to each well. The plates wereincubated for 30 min at 37°C and washed eight times, and the amountof bound peroxidase was determined with ABTS [2,2'-azino-bis(3-ethylbenzthiazoline-6-sulfonicacid)] substrate as described previously (37, 51). The absorbanceat 405 nm was read with a Labsystems (Helsinki, Finland) iEMSreader with a built-in software package for data analysis. Thetiter of each serum sample was arbitrarily set as the maximumdilution that yielded at least twice the absorbance of the samedilution of nonimmune controlserum.

For the determination of antiserum specificity and sensitivity for pediocin PA-1, three types of ELISAs were designed. Inthe noncompetitive indirect ELISA (NCI-ELISA), microtiter plateswere coated essentially as described by Bubert et al. (8).Briefly, wells of microtiter plates were coated with 100 µl ofdifferent concentrations of PH2-OAM, PH2-OAG, PH1-OAG, pure pediocinPA-1, pure nisin A, pure OA, or neutralized and filter-sterilizedsupernatants from several LAB strains in CB. The plates were maintainedfor 3 h at 40°C and then were blocked and washed as describedfor the antiserum titration procedure. Next, 50 µl of antiserum(diluted 1:1,000 in PBS) was added, and the plates were incubatedfor 1 h at 37°C. After a washing step and the addition of goatanti-rabbit IgG-peroxidase conjugate (diluted 1:500 in OA-PBS),the amount of bound peroxidase was determined with ABTS substrateas described previously. The increase in the absorbance was proportionalto the amount of specific antigen in thesamples.

In the competitive indirect ELISA (CI-ELISA), microtiter plates were coated with 100 µl of either PH2-OAG (0.75 µg/ml) orpediocin PA-1 (2 µg/ml) in CB and then were blocked and washedas described for the antiserum titration procedure. Next, 50 µlof different concentrations of standards (PH2 or pediocin PA-1dissolved in PBS or MRS broth; Oxoid Ltd., Basingstoke, UnitedKingdom), control samples (PH1, pure nisin A, and pure OA dissolvedin PBS), or neutralized and filter-sterilized supernatants fromseveral LAB strains was incubated with 50 µl of antiserum (diluted1:1,000 in PBS) over the solid-coated phase for 1 h at 37°C. Theamount of bound antibody was determined by the addition of anti-rabbitIgG-peroxidase conjugate as described previously. Relative antibodyaffinity was arbitrarily set as the bacteriocin concentrationrequired to inhibit antibody binding by 50%.

A CD-ELISA was also developed essentially as previously described (37, 51). In this assay, the plates were coated overnightby air drying at 40°C with 125 µl of PH2-KLH-generated antibodiesdiluted in CB. After washing and blocking were performed, 50 µlof standards, control samples, or samples such as those describedfor the CI-ELISA and 50 µl of either PH2-HRP (diluted 1:500 inOA-PBS) or pedA1-HRP (diluted 1:250 in OA-PBS) were added to eachwell consecutively. After 1 h of incubation at 37°C, the plateswere washed and the amount of bound peroxidase was determinedby the addition of ABTS substrate. Relative antibody affinitywas arbitrarily set as describedpreviously.

For all immunoassays, the concentrations of antibodies, hapten conjugates, or enzyme tracers were optimized by checkerboardtitration. Competition curves were obtained by plotting absorbanceagainst the logarithm of the analyte concentration. Sigmoid curveswere fitted to a four-parameter logistic equation (24) by useof the Labsystems software package (Genesis version 1.60).

Slot dot assay. Eighty microliters of different concentrations of PH2-OAG, PH1-OAG, OA, pediocin PA-1, or pure nisin A dissolved in MRS brothand the same volume of neutralized and filter-sterilized supernatantsfrom 16-h cultures of various LAB strains were deposited ontoa nitrocellulose membrane (pore size, 0.2 µm; Bio-Rad Laboratories,Richmond, Calif.) in a Bio-dot SF microfiltration apparatus (Bio-RadLaboratories). Nonspecific binding sites were blocked by immersingthe membrane in 5% skim milk in PBS-Tween (1%) for 1 h at 37°Con an orbital shaker. The membrane was washed with PBS-Tween oncefor 15 min and twice for 5 min. The membrane was incubated with30 ml of PH2-KLH-generated antibodies (diluted 1:1,000 in PBS)for 1 h at 37°C. The membrane was washed as described above andthen incubated with 30 ml of goat anti-rabbit IgG-peroxidase conjugate(diluted 1:5,000 in blocking solution) for 1 h at 37°C. Aftera wash as described above, specific antigens for PH2-KLH-generatedantibodies were visualized by chemiluminescence with an ECL detectionkit (Amersham, Amersham, United Kingdom). The light emission wasdetected by a short exposure of the membrane to blue-light-sensitiveautoradiography film (Hyperfilm ECL; Amersham). The concentrationof pediocin PA-1 in the supernatant of P. acidilactici 347 wasquantitated from the resulting standard curve of the pediocinPA-1 response by scanning and digitizing of the autoradiographypaper by use of an image-analyzing system and the computer programMolecular Analyst (version 1.5; Bio-RadLaboratories).

Microorganisms, media, and bacteriocin assays. The LAB strains tested for pediocin PA-1 production or antibody cross-reactivity are listed in Table 1. All microorganismswere propagated in MRS broth at 32°C, and supernatants obtainedby centrifugation at 12,000 × g for 10 min at 4°C were adjustedto pH 6.2 with 1 N NaOH, filtered through 0.2-µm-pore-size filters(PES 25-mm GD/X sterile syringe filters; Whatman, Maidstone, UnitedKingdom), and stored at $-$ 20°C until use. The antimicrobial activityof the supernatants was evaluated by an agar diffusion test (ADT)or by a microtiter plate assay (MPA).

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TABLE 1. Reactivities of serum polyclonal antibodies against culture supernatants of LAB strains as determined by NCI-ELISA, CI-ELISA, and CD-ELISA

The ADT was performed as described by Cintas et al. (12). Briefly, 50-µl aliquots of supernatants were placed in wells (6-mmdiameter) cut in cooled soft MRS agar plates (20 ml) previouslyseeded (10⁵ CFU/ml) with the appropriate indicator microorganisms. After2 h at 4°C, the plates were incubated at 32°C for growth of thetarget organism; after 24 h, the diameters (millimeters) of thegrowth inhibition zones were measured, and the area of the haloswas calculated as the area of the resulting circularcrown.

The MPA was performed basically as described by Holo et al. (29). Each well of the microtiter plate contained 50 µl of atwofold serial dilution (in MRS broth) of a bacteriocin sampleand 150 µl of a diluted (in MRS broth) fresh overnight cultureof the indicator microorganism (approximately 2 × 10⁷ CFU ml¹). Growth inhibition was measured spectrophotometrically at 620nm with a microtiter plate reader (Labsystems iEMS reader) after14 h of incubation at 32°C. One bacteriocin unit was defined asthe reciprocal of the highest dilution of the bacteriocin causing50% growth inhibition (50% of the turbidity of the control culturewithout bacteriocin). Derivatives of P. acidilactici 347 (Ped) were selected by growth of this strain in MRS broth with novobiocin(10 µg/ml), and several isolates were obtained on MRS agar plates.The antimicrobial activity of these isolates was evaluated byan ADT. For isolates not displaying antimicrobial activity, theabsence of the functional pedA gene was determined by a PCR test.The primers, conditions for amplification, and visualization ofthe 711-bp DNA fragment containing the pedA and pedB genes ofthe pediocin PA-1 operon were as previously described (45).

Purification of pediocin PA-1. The antimicrobial compound of P. acidilactici 347, used as the source of pediocin PA-1, was purified to homogeneity as previouslydescribed for other bacteriocins (12, 13). A gel filtrationstep with a Sephadex G-25 gel filtration column (Pharmacia LKB,Uppsala, Sweden) was introduced after ammonium sulfate precipitationof the neutralized and filter-sterilized supernatants. The gelfiltration sample equilibrated in 20 mM sodium phosphate bufferwas successively subjected to cation-exchange, hydrophobic interaction,and RP chromatography (PepRPC HR5/5 column in a fast protein liquidchromatography system; Pharmacia). The RP fraction containingthe bacteriocin was desiccated by rotary evaporation and resuspendedin an equivalent volume of deionized water. The bacteriocin activityduring the purification process was determined by the MPA as previouslydescribed. The final concentration of the pure bacteriocin wasestimated by use of the extinction coefficient of pediocin PA-1(an A₂₈₀ of 3.1 corresponds to 1 mg/ml).

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Purification of pediocin PA-1. Crucial to this research has been obtaining sufficient amounts of purified pediocin PA-1. The results of a procedure for pediocinPA-1 purification from a late-logarithmic-growth-phase cultureof P. acidilactici 347 grown at 32°C in MRS broth are summarizedin Table 2. Ammonium sulfate precipitation allowed for a 14-foldincrease in specific antimicrobial activity and a 76% recoveryof bacteriocin activity. The 10-ml fraction eluted from the hydrophobicinteraction column contained 47% of the initial antimicrobialactivity. RP chromatography resulted in a single absorbance peakcoinciding with the antimicrobial activity, and the purity ofthe sample was confirmed by amino acid sequencing. The final specificactivity of pediocin PA-1 was approximately 319,000-fold greaterthan that in the culture supernatant, with a 715% recovery ofthe initial bacteriocin activity. The final amount of pediocinPA-1 purified from the described purification process was calculatedto be 520 µg.

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TABLE 2. Purification of pediocin PA-1

Sensitivity and specificity of the antipeptide antibodies for pediocin PA-1. The chemically synthesized peptide of 11 amino acids comprising the C-terminal fragment of pediocin PA-1 was conjugated toKLH through the C-terminal cysteine group of the peptide, andthe conjugate was used in the immunization of rabbits. On day28 of the immunization process and after three doses of the immunogenhad been administered, the animals had apparent titers in serumof 1:25,000 to 1:51,200; the titers increased slightly up to 1:102,000with three more booster doses. A mixture of the resulting serafrom the immunized animals was usedthroughout.

The determination of pediocin PA-1-specific antibodies in the sera of immunized animals was initially performed by an NCI-ELISA.The results shown in Fig. 1 indicate that polyclonal antibodiesrecognized peptide fragment PH2 conjugated to OA through the maleimidemethod (PH2-OAM) and the fragment conjugated to OA through theglutaraldehyde method (PH2-OAG), suggesting that a large numberof antibodies recognized the same biochemical bridge between thepeptide fragment and the carrier protein molecule or that theconjugation method affected the conformation or exposure of theepitopes to the antibodies. More importantly, the antibodies recognizedpediocin PA-1 present in the wells of the microtiter plates. Nevertheless,recognition was higher for pediocin PA-1 in CB than in MRS broth.The detection limits for pediocin PA-1 were 0.025 µg/ml in CBand 1 µg/ml in MRS broth, while such antibodies did not detectthe presence in the wells of the microtiter plates of equivalentconcentrations of OA, PH1-OAG, or pure nisin A.

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FIG. 1. Results of an NCI-ELISA for the detection of PH2-OAM (

), PH2-OAG ( $bullet$ ), PH1-OAG ( $black-triangle$ ), purified pediocin PA-1 in CB (

), purified pediocin PA-1 in MRS broth ( $open circle$ ), pure nisin A in CB ( $black-lozenge$ ), and pure OA in CB (+).

The specificity for pediocin PA-1 of the PH2-KLH-generated antibodies was also investigated by a CI-ELISA. In this assay,the plates were coated with PH2-OAG (Fig. 2A) or pediocin PA-1(Fig. 2B). The average detection limit for fragment PH2 was lessthan 0.025 µg/ml on both types of plates, while for pediocin PA-1the detection limits were 0.5 µg/ml in PBS and 0.05 µg/ml in MRSbroth on plates coated with PH2-OAG and 0.5 µg/ml in PBS and 0.25µg/ml in MRS broth on plates coated with pediocin PA-1. The amountof free PH2 required for 50% binding inhibition ranged from 0.5to 1 µg/ml on both types of plates, while for pediocin PA-1 dissolvedin PBS, this value was 40 µg/ml on both types of plates. Similarly,the amounts of free pediocin PA-1 required for 50% binding inhibitionwere 20 µg/ml for plates coated with PH2-OAG and 10 µg/ml forplates coated with pediocin PA-1 when the purified bacteriocinwas dissolved in MRS broth. The performance of this assay wasimproved when pediocin PA-1 was used as the solid-phase antigen,thus increasing the relative antibody-binding affinity and decreasingthe free pediocin PA-1 concentration required to inhibit antibodybinding.

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FIG. 2. Results of a CI-ELISA for recognition of the PH2 fragment in PBS (

) and MRS broth ( $bullet$ ), purified pediocin PA-1 in PBS (

) and MRS broth ( $open circle$ ), and the PH1 fragment ( $black-triangle$ ), pure OA (+), and pure nisin A ( $black-lozenge$ ) in PBS by use of microtiter ELISA plates coated with PH2-OAG (A) or purified pediocin PA-1 (B).

Finally, a CD-ELISA was also developed to determine the specificity for pediocin PA-1 of the PH2-KLH-generated antibodies.In this assay, the plates were coated with an appropriate dilutionof the sera of immunized animals and with HRP conjugated to eitherPH2 (Fig. 3A) or pediocin PA-1 (Fig. 3B). As shown in Fig. 3A,pediocin PA-1 did not effectively compete with PH2-HRP for bindingto the antibody-coated microtiter plates, while the bacteriocincompeted much more effectively with pedA1-HRP for binding to theantibodies. In the latter case (Fig. 3B), the minimum detectionlimit for fragment PH2 and pediocin PA-1 in either PBS or MRSbroth was less than 0.025 µg/ml. Similarly, the amount of freePH2 required for 50% binding inhibition ranged from 0.1 to 0.5µg/ml in either PBS or MRS broth, while for pediocin PA-1, thesevalues were 5 µg/ml in PBS and 0.5 µg/ml in MRS broth. The assaysensitivity for detecting free pediocin PA-1 concentrations wasimproved significantly with pedA1-HRP, confirming the high affinityof the generated antibodies for the PH2 fragment and the advantagesof developing immunoassays in which complete bacteriocin molecules,either free or conjugated, compete for antibody binding.

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FIG. 3. Results of a CD-ELISA for recognition of the PH2 fragment in PBS (

) and MRS broth ( $bullet$ ), purified pediocin PA-1 in PBS (

Immunoreactivity of the antipeptide antibodies to different bacteriocins. The specificities of the serum polyclonal antibodies in neutralized and filter-sterilized supernatants of 16-h cultures ofvarious LAB strains were evaluated by NCI-ELISA, CI-ELISA, andCD-ELISA (Table 1). All immunoassays reacted with the supernatantof P. acidilactici 347, a pediocin PA-1-producing strain (45),but did not react with the supernatant of a derivative of P. acidilactici347 (Ped), a non-pediocin PA-1-producing strain. The isolation of non-bacteriocin-producingstrains is important in the evaluation of the specificity andimmunoreactivity of antipeptide antibodies, since the only differencebetween them and the wild-type producing strain is the absenceof bacteriocinogenic activity in their supernatants. No reactivityor negligible reactivity was observed with the supernatants ofPediococcus pentosaceous FBB61, a pediocin A producer (43),Enterococcus faecium T136, an enterocin A and B producer (10),E. faecium P13, an enterocin P producer (9, 13), E. faeciumL50, an enterocin L50A and L50B producer (14), Enterococcusfaecalis INIA4, an enterocin AS-48 producer (33), Lactobacillussake 148, a lactocin S producer (46), Lactococcus lactis BB24,a nisin A producer (46), and L. lactis MG1614, a nonbacteriocinproducer (20). Table 3 shows the alignment of mature pediocinPA-1 with other pediocin-like bacteriocins. It is important tostress that enterocins A and P share the N-terminal consensusamino acid motif (YGNGVxC) of the pediocin family of bacteriocins,as well as other, shorter motifs within their molecules, whileenterocin B shares only the short consensus motif (AWAxG) on theC-terminal part of pediocin PA-1.

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TABLE 3. Alignment of mature pediocin PA-1 with other pediocin-like bacteriocins^a

The evaluation by NCI-ELISA, CI-ELISA, CD-ELISA, ADT, and MPA of the concentration of pediocin PA-1 in the supernatant ofa 16-h culture of P. acidilactici 347 grown in MRS broth is shownin Fig. 4. The concentrations of pediocin PA-1 were determinedto be 8,943 ng/ml by the MPA and 8,719 ng/ml by the ADT, whilethe concentrations were lower but similar in all immunoassays(5,059 ng/ml in the NCI-ELISA, 5,108 ng/ml in the CI-ELISA, and5,133 ng/ml in the CD-ELISA). The relationship between the pediocinPA-1 concentrations detected by the antimicrobial tests and thosedetected by the immunoassays was also evaluated. Figure 5A showsthe relationship between the ADT and the immunoassays and Fig.5B shows that between the MPA and the immunoassays for pediocinPA-1 concentrations of 25 to 9,000 ng/ml. Significant (P < 0.0001)regression equations were established for pediocin PA-1 concentrationsdetected by the ADT and the immunoassays (r², 0.998 to 0.996) and by the MPA and the immunoassays (r², 0.972 to 0.951).

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FIG. 4. Comparative recognition by NCI-ELISA (A), CI-ELISA (B), CD-ELISA (C), ADT (D), and MPA (E) of pediocin PA-1 in a supernatant of P. acidilactici 347 grown in MRS broth.

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FIG. 5. Relationship between pediocin PA-1 concentrations determined by the ADT (A) and the MPA (B) and the NCI-ELISA (

), CI-ELISA ( $diamond$ ), and CD-ELISA ( $open circle$ ). The regression equations for panel A were as follows: y_NCI-ELISA = 222.7 $-$ 0.39x + 1.06e $-$ 3x² $-$ 1.28e $-$ 7x³ (r², 0.997); y_CI-ELISA = 167.0 $-$ 5.44e $-$ 2x + 7.13e $-$ 4x² $-$ 7.34e $-$ 8x³ (r², 0.996); and y_CD-ELISA = 198.5 $-$ 0.44x + 1.11e $-$ 3x² $-$ 1.36e $-$ 7x³ (r², 0.998). The regression equations for panel B were as follows: y_NCI-ELISA = 264.7 $-$ 2.15x + 1.76e $-$ 3x² $-$ 1.96e $-$ 7x³ (r², 0.951); y_CI-ELISA = 177.2 $-$ 1.52x + 1.22e $-$ 3x² $-$ 1.14e $-$ 7x³ (r², 0.957); and y_CD-ELISA = 342.5 $-$ 2.42x + 1.94e $-$ 3x² $-$ 2.23e $-$ 7x³ (r², 0.972).

The immunoreactivity of the PH2-KLH-generated antibodies to different conjugates, standards, and bacteriocins was also evaluatedby immunodotting. Results of the slot dot assay of standards andsupernatants of 16-h cultures of various LAB strains probed withthe PH2-KLH-generated antibodies (Fig. 6) clearly indicated thatthe antibodies recognized fragment PH2 but not fragment PH1, OA,or pure nisin A. Similarly, the antibodies recognized pediocinPA-1 at a detection limit of 2.5 µg/ml; they were capable of recognizingthis bacteriocin only in the supernatant of P. acidilacti 347,a pediocin PA-1-producing strain. There was no detectable cross-reactivitywith supernatants of different LAB strains that produced or didnot produce bacteriocins. The concentration of pediocin PA-1 inthe supernatant of P. acidilactici 347 was calculated to be 3,702ng/ml by an image-analyzing system and a computer program. Thelower sensitivity of this assay for the detection and quantificationof pediocin PA-1 than of the previously described immunoassaysmay be attributable to the lower affinity of the bacteriocin forattachment to the nitrocellulose paper, to the displacement orcompeting effect of the components of MRS broth for attachmentto the paper, or to the effect or strength of the washing stepsused for the removal of the attached bacteriocin molecules.

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FIG. 6. Slot dot assay of various standards and supernatants from LAB strains with the PH2-KLH-generated antibodies. Row A contained PH2-OAG at 10 µg/ml (lane 1), 5 µg/ml (lane 2), 2.5 µg/ml (lane 3), 1 µg/ml (lane 4), and 0.5 µg/ml (lane 5); lane 6, no conjugate Row B contained PH1-OAG, row C contained pure OA, row D contained purified pediocin PA-1, and row E contained pure nisin A, all in MRS broth at the same concentrations as those described for row A (lanes 1 to 6). Row F contained supernatants from P. acidilactici 347 (lanes 1 and 2), E. faecium P13 (lanes 3 and 4), and E. faecium T136 (lanes 5 and 6). Row G contained supernatants from E. faecium L50 (lanes 1 and 2), E. faecalis INIA4 (lanes 3 and 4), and L. sake 148 (lanes 5 and 6). Row H contained supernatants from P. pentosaceous FBB61 (lanes 1 and 2), L. lactis BB24 (lanes 3 and 4), L. lactis MG1614 (lane 5), and P. acidilactici 347 (Ped) (lane 6).

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

Contrary to the situation for other bacteriocins, such as nisin A, commercial preparations of pure pediocin PA-1 are not yetavailable. Integral to this research was the purification of sufficientpediocin PA-1 to be used in competitive immunoassays as the solid-phaseantigen or conjugated to HRP as the competing reagent for bindingto antibody-coated microtiter plates. Pediocin PA-1 was also usedfor the construction of reference curves for cross-reactivitydeterminations or determination of pediocin PA-1 concentrationsin the supernatant of the producing strain. Comparison of ourpurification procedure (Table 2) for this bacteriocin with thoseof others (27, 42) indicates that the introduction of a gelfiltration step after ammonium sulfate precipitation increasesboth the specific activity and the final yield of the purifiedfraction. The gel filtration step reduces the presence of contaminantsand increases the binding of the bacteriocin to the cation-exchangeresin. The introduction of such a gel filtration step has provenuseful in the purification of other bacteriocins, such as enterocinB (10) and enterocin P (13). Increases in activity after hydrophobicinteraction chromatography during the purification of many bacteriocinshave been reported. The apparent increases may be the result ofthe removal of bacteriocin activity inhibitors during the purificationor of a conformational change of the molecule to a more activeform in the hydrophobic solvent (13, 47).

Although previous reports have described the generation of antibodies against nisin A (18, 49, 51), pediocin AcH (6),and pediocin RS2 (5), in all of these cases, antibodies weregenerated against the whole bacteriocin molecule either aloneor conjugated to a carrier protein. However, such an approachmay not be appropriate for generating antibodies against bacteriocinssharing common amino acids and consensus motifs. Since pediocinPA-1 belongs to the pediocin family of bacteriocins, it exhibitshigh homology with other bacteriocins, such as carnobacteriocinA (59), acidocin A (35), bacteriocin 31 (55), bavaricinMN (34), carnobacteriocins BM1 and B2 (44), curvacin A (53),enterocin A (2), leucocin A (23), piscicocin V1a (4),mesentericin Y105 (25), sakacin P (54), and enterocin P (13).Therefore, an alternative approach had to be taken. Closely relatedproteins have been distinguished by use of antisera as a probefor a specific substrate within the protein (21). Our approachconsisted of conjugation of a chemically synthesized fragmentderived from the C-terminal fragment of pediocin PA-1 to a carrierprotein for use as the immunogen for the generation of high-affinityserum-specificantibodies.

Most researchers agree that in order to produce antibodies against small peptides, it is necessary to enhance their immunogenicityby coupling them to protein carriers. Furthermore, when shortpeptides are used as the immobilized antigen in solid-phase immunoassays,it is also necessary to use peptide-carrier conjugates, sincepeptides of 6 to 15 residues generally do not bind adequatelyto plastic surfaces (22, 56). KLH was selected as the carrierprotein because of its immunogenicity. The potential immunogenicityof fragment PH2 was evaluated based on hydrophilicity and antigenicindex by use of the Sequence Analysis Software Package (16)licensed from the Genetics Computer Group program. The sequencealignment of prepeptides of the pediocin family of bacteriocinsrevealed the existence at residues 32 to 36 of the pediocin PA-1molecule of a GWAxG consensus motif (10) that may be importantfor structure-function relationships (19). Peptide fragmentPH2 was conjugated to KLH by the maleimide method for use as theimmunogen and to OA by the glutaraldehyde method for use as thesolid support to prevent interference in the immunoassays by antibodiesrecognizing the same chemical bridge between the peptide and thecarrier. Similarly, peptide fragment PH2 and pediocin PA-1 wereconjugated to HRP by the periodate method for use in the CD-ELISA.

The specificity of the PH2-KLH-generated rabbit polyclonal antibodies for pediocin PA-1 was demonstrated by NCI-ELISA, CI-ELISA,CD-ELISA, and immunodotting. The importance of the developmentof proper immunoassay formats should be emphasized (51). Inthis study, the presence of pediocin PA-1-specific PH2-KLH-generatedantibodies could be demonstrated in all immunoassays, indicatingthe efficacy of the selected fragment and protein carrier in thegeneration of the antibodies and the appropriateness of the conjugationmethods and immunoassay formats; these methods and formats excludedthe detection of other antibodies that may have had a strongeraffinity for the bacteriocin carrier bridge or a conjugation by-productand interfered in the competition between the free bacteriocinand the conjugates for antibodybinding.

As expected, the affinity of the PH2-KLH-generated antibodies for PH2 was slightly higher than that for pediocin PA-1. Thisresult was shown by the lower limit of detection of the fragment(<0.025 µg/ml) as well as the smaller amount of free PH2 neededfor 50% inhibition (0.1 to 0.5 µg/ml) in all immunoassays. Thelimits of detection of pediocin PA-1 in the NCI-ELISA were 0.025µg/ml in CB and 1 µg/ml in MRS broth, reflecting the masking effectof the medium on the detection of the bacteriocin. This maskingeffect may have been due to competition between the componentsin the medium and the free bacteriocin for attachment to the wellsof the microtiter plates. However, in the CI-ELISA, coating ofthe plates with pediocin PA-1 enhanced the detection of free pediocinPA-1; when pediocin PA-1 estimations were made with MRS broth,the detection limit of the immunoassay was improved to 0.025 µg/mland 50% binding inhibition was achieved with 10 µg of pediocinPA-1/ml. Moreover, the development of a CD-ELISA with pedA1-HRPas the conjugate increased the affinity of the PH2-KLH-generatedantibodies for free pediocin PA-1. The limit of detection of pediocinPA-1 in MRS broth was less than 0.025 µg/ml, and 50% binding inhibitionwas achieved with 0.5 µg of pediocin PA-1/ml.

Competition curves for pediocin PA-1 in PBS and MRS broth differed notably, showing higher binding inhibition values in MRSbroth (Fig. 2 and 3). The binding differences in the competitioncurves could have been due to the different pHs of the menstruums,which were 6.1 to 6.2 for MRS broth and 7.2 to 7.4 for PBS (51).The different pHs could have affected pediocin PA-1 solubilityor a variable antigen-antibody interaction, which would have affectedthe sensitivity of the immunoassays. The limit of detection andsensitivity of the immunoassays developed for pediocin PA-1 werein the ranges of the values cited for nisin A immunoassays (18,51) but were more effective than those of the monoclonal antibody-basedimmunoassay developed for pediocin RS2 (5).

The PH2-KLH-generated polyclonal antibodies produced in this study showed a high affinity for pediocin PA-1 in the supernatantof a producing strain grown in MRS broth (Table 2). The antibodiesdid not show cross-reactivity with other bacteriocins, eitherlantibiotic nor nonlantibiotic. The antibodies also did not showany significant cross-reactivity with enterocins A, B, and P,which share consensus amino acid motifs with pediocin PA-1 (Table3). This absence of cross-reactivity is not surprising, sinceit has been suggested that changes in a single amino acid residuein a peptide fragment drastically affect protein recognition (48).

Pediocin PA-1 produced by P. acidilactici 347 in MRS broth was detected by all immunoassays (Table 1 and Fig. 4) as wellas by immunodotting (Fig. 6). The lower level of detection ofpediocin PA-1 by the immunoassays than by the biological assaysmay reflect differences in pediocin PA-1 solubility, the conformationof the native bacteriocin, aggregation of the bacteriocin moleculeswith components of MRS broth, or the oxidation of amino acid residues.These factors may affect the conformation of the molecules andsubsequently the sensitivity of theimmunoassays.

Purified pediocin PA-1 has been shown by capillary electrophoresis analysis to have a mixture of two peptide forms: oxidizedand nonoxidized (15). The oxidation of cysteine residues oflactococcin B and leucocin A affected the antimicrobial activityof those bacteriocins (23, 58), while sakacin A activity wasnot affected by oxidation (28). Nevertheless, significant regressionequations for determining pediocin PA-1 concentrations have beenobtained (Fig. 5) by use of the two antimicrobial tests and thethree immunoassays. These results suggest the usefulness of theimmunoassays for the detection and quantification of pediocinPA-1 in the supernatants of producing microorganisms and in acomplex medium such as MRSbroth.

The strategy of using a synthetic peptide for predetermining the specificity of antibodies against a protein epitope has shownboth conceptual simplicity and practical convenience. Althougha previous attempt by our group was unsuccessful in the generationof specific antibodies against pediocin PA-1 (37), the presentwork reports for the first time, to our knowledge, the efficientproduction of high-affinity serum-specific polyclonal antibodiesof predetermined specificity for pediocin PA-1. All of the techniquesdescribed here for the selection of the peptide fragment and carriermolecule, conjugation methods, and immunoassay development canbe used as models for the generation of antibodies against otherbacteriocins and for the development of immunochemical techniquesfor the sensitive and rapid detection of antimicrobial peptidesof interest in the food industry. Potential applications of theseantibodies include the rapid identification and isolation of pediocinPA-1-producing strains from many sources (3, 17). Similarly,the pediocin PA-1-specific antibodies may be applied to the analysisby ELISAs of pediocin PA-1 in foods and as a tool for the regulationof bacteriocin production and in structure-function studies. Ofgreat interest is the generation of specific antibodies to well-characterizedbacteriocins for studies on the expression of multiple bacteriocinsin heterologous hosts. Finally, the antibodies described in thiswork can be used for the purification of pediocin PA-1 in a singlestep based on the use of immunoaffinity chromatographystrategies.

	ACKNOWLEDGMENTS

This work was partially supported by grant ALI97-0559 from the Comisión Interministerial de Ciencia y Tecnología (CICYT),Madrid, Spain, and by contract BIOT-CT94-3055 from The Commissionof the European Communities. J.M.M. holds a fellowship from theComunidad Autónoma de Madrid; M.I.M. is a researcher workingunder the European Contract; A.M.S. is the recipient of a fellowshipfrom the Instituto Danone, Barcelona, Spain; and C.H. holds afellowship from the Ministerio de Educación y Ciencia, Madrid,Spain.

We are grateful to J. Vázquez (Centro de Biología Molecular Severo Ochoa, Madrid, Spain) for the chemical synthesis of thepeptidefragments.

	FOOTNOTES

^* Corresponding author. Mailing address: Departamento de Nutrición y Bromatología III, Facultad de Veterinaria, UniversidadComplutense, 28040 Madrid, Spain. Phone: 34-91-3943752. Fax: 34-91-3943743.E-mail: ehernan{at}eucmax.sim.ucm.es.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
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Martínez, J. M., Kok, J., Sanders, J. W., Hernández, P. E. (2000). Heterologous Coproduction of Enterocin A and Pediocin PA-1 by Lactococcus lactis: Detection by Specific Peptide-Directed Antibodies. Appl. Environ. Microbiol. 66: 3543-3549 [Abstract] [Full Text]
Guyonnet, D., Fremaux, C., Cenatiempo, Y., Berjeaud, J. M. (2000). Method for Rapid Purification of Class IIa Bacteriocins and Comparison of Their Activities. Appl. Environ. Microbiol. 66: 1744-1748 [Abstract] [Full Text]

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