Distribution of Microbes Producing Antimicrobial {varepsilon}-Poly-L-Lysine Polymers in Soil Microflora Determined by a Novel Method

We developed a simple and sensitive screening method to investigatethe distribution of microbes producing an antimicrobial poly(aminoacid), ${varepsilon}$ -poly-L-lysine ( ${varepsilon}$ -PL), in microflora. An acidic dye, PolyR-478, incorporated in an agar plate detected ${varepsilon}$ -PL producersby electrostatic interaction with the secreted basic polymers.All ${varepsilon}$ -PL producers, isolated after careful and sufficient screeningof soil microflora, belonged exclusively to two groups of bacteriaof the family Streptomycetaceae and ergot fungi. They were characterizedbased on the density and diameter of the concentric zone formedby the secreted polymers. The density depended on each isolate.The increase in the diameter of the concentric zone per unitof time varied among isolates and was negatively correlatedwith the molecular weight. Although the distribution of ${varepsilon}$ -PLproducers was extremely limited, their products were structurallyvaried. The molecular masses of the secreted polymers amongthe isolates ranged from 0.8 to 2.0 kDa. There were also isolatesproducing unknown polymers inconsistent with the correlationor producing a mixture of polymers with original and modifiedstructures. A chemically modified polymer was an ${varepsilon}$ -PL derivative,as determined by mass spectrometry. Since the structural variationshad no relation to the phylogenetic position of the isolates,it is possible that enzymes involved in the synthesis diversifiedafter putative horizontal transfers of relevant genes.

INTRODUCTION

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Introduction

${varepsilon}$ -Poly-L-lysine ( ${varepsilon}$ -PL) is a basic homopolymer that consists of20 to 30 residues of L-lysine with an ${varepsilon}$ amino group- ${alpha}$ carboxylgroup linkage (10). It was accidentally found as an extracellularmaterial produced by the filamentous bacterium Streptomycesalbulus during a screening of Dragendorff's reagent-positivesubstances (11). This polymer has antimicrobial activity againsta wide spectrum of microbes. Moreover, it is harmless to humansand biodegradable; thus, it has been widely used in food manufacturingas a safe preservative. The ${varepsilon}$ -PL-producing strain is resistantto its product, ${varepsilon}$ -PL, but the resistance mechanism is unknown.Recently, ${varepsilon}$ -PL-degrading enzyme has been reported to be a cellmembrane-associated protein in the strain (6) as well as inan ${varepsilon}$ -PL-tolerant bacterium, Sphingobacterium (7).

Which microbial species produce ${varepsilon}$ -PL in the natural habitat remainsunclear. Aside from S. albulus, a filamentous fungus, Clavicepspurpurea, has been described to produce an ${varepsilon}$ -PL-like polymerthat is rich in ${varepsilon}$ -amide bonds (12). Although the distributionof ${varepsilon}$ -PL producers beyond the trans-kingdom distance is a subjectof interest, there has been no screening method appropriatefor an exhaustive exploration. The conventional screening methodfor detecting ${varepsilon}$ -PL is to assay the extracellular substances secretedinto individual culture fluids. However, this is inadequateto examine a large number of microbes. Here, we report a novel,simple, and sensitive screening method that can overcome thisproblem. The principle of the screening method is to detectthe interaction between charged groups of secreted polypeptidesand basic or acidic dyes. Because this novel method is applicableto a solid culture medium, it is possible to examine numerousmicrobes at one time. By using this method, an exhaustive screeningwas carried out to examine the distribution of ${varepsilon}$ -PL producers.

While the original ${varepsilon}$ -PL-producing strain has been bred to increaseits productivity (4), natural microbial resources have beenexplored to find other strains with more advantageous propertiesfor application: for example, those that produce polymers oflower molecular weight (13). Generally, it is reasonable toseek stronger antimicrobial activity among naturally occurringderivatives. Here, we examined whether this novel screeningmethod can be used to determine strains with potential industrialuse or structural derivatives.

MATERIALS AND METHODS

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Materials and Methods

Screening for microbes with ${varepsilon}$ -PL-producing activity.
Screenings were carried out by streaking samples on agar platescontaining either basic or acidic dyes. Samples were collectedmainly from forest soil. The dyes used here, Poly R-478 (Fig.1) and Remazol Brilliant Blue-R (RBBR), were purchased fromSigma (St. Louis, Mo.). Typically, a synthetic glycerol (SG)medium containing 0.02% Poly R-478 was used for the primaryscreening. The SG medium was composed of 10 g of glycerol, 0.66g of ammonium sulfate, 0.68 g of sodium dihydrogen phosphate,0.25 g of magnesium phosphate heptahydrate, 0.1 g of yeast extract,and 1 ml of Kirk's mineral solution (5) in 1 liter. The pH wasadjusted to 7.0, and the medium was solidified by adding 1.5%agar. After incubation at 28°C for about 1 week, microbesforming specific colonies interacting with dyes were pickedup and purified after several culture transfers. As a control,an ${varepsilon}$ -PL-nonproducing strain, Streptomyces kifunensis (Kitasatosporiakifunense) IFO15206, which was provided by the Institute forFermentation, Osaka, Japan, was used.

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FIG. 1. Chemical structures of acidic dye Poly R-478 and basic dye methylene blue.

Production and extraction of ${varepsilon}$ -PL.
Isolates were inoculated on the surface of SG agar plates withoutdye. To be able to track the diffusion of polymers, isolateswere simultaneously cultured on other plates with the same medium,but containing Poly R-478. After 2 weeks of incubation at 28°C,the secreted products were excised from the area surroundingeach colony as small agar pieces. To eliminate impurities inthe medium ingredients, the agar pieces were immersed in waterseveral times. After freeze-drying, the agar pieces were allowedto swell by immersion in 1 N HCl and heated at 100°C for1 h to destroy the agar matrix. Alternatively, ${varepsilon}$ -PL was elutedfrom agar pieces in an electric field in the presence of 0.1%sodium dodecyl sulfate (SDS) buffered with 25 mM Tris HCl (pH8.0). The eluted polymer was dialyzed against water, and thedialysate was dried in vacuum.

Analytical techniques.
In order to determine the linking pattern of monomers, an extractedpolymer was derived by using the 2,4-dinitrophenol (DNP) groupand then hydrolyzed completely by heating in 6 N HCl at 100°Cfor 20 h (10). The reaction products were subjected to thin-layerchromatography (TLC; plate, silica gel 60 [Merck]; developer,n-butanol-acetic acid-pyridine-water at 4:1:1:2; detection,ninhydrin reagent). For the determination of molecular weight,polymers extracted by the moderate acid treatment (1 N HCl,100°C, 1 h) were further purified with a cation-exchangeresin, Amberlite IRC-50 (Organo) (10), and analyzed by polyacrylamidegel electrophoresis (PAGE) in the presence of 0.1% SDS (gel,16.5% polyacrylamide; stain, CBB-G250). The equipment and allreagents for SDS-PAGE were obtained from Bio-Rad Laboratories.As an authentic standard, commercially supplied ${varepsilon}$ -PL (Wako PureChemical Industries, Osaka, Japan) was used. Mass spectrometry(MS) of the polymer was carried out by matrix-assisted laserdesorption ionization-time-of-flight MS (MALDI-TOF) MS (modelVoyager DE spectrometer; PerSeptive Biosystems). Samples wereprepared by mixing electroeluted polymers with ${alpha}$ -cyano-4-hydroxycinnamicacid.

Identification and phylogenetic analysis of isolates.
Taxonomic identification of isolates was deputed to the NationalCollections of Industrial, Food and Marine Bacteria (Shizuoka,Japan). Phylogenetic grouping was carried out by the neighbor-joiningmethod on the basis of 16S and 28S rRNA sequence data for Streptomycetaceaeand fungi, respectively.

RESULTS

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Results

Screening for ${varepsilon}$ -PL producers on an agar plate containing a charged dye.
With an acidic polymeric dye, Poly R-478 (0.02%), microbes producingextracellular basic polymers could be visualized as a distinctcolony on an agar plate. For example, in the agar plate on whichK. kifunense strain MN-1 (Streptomycetaceae), isolated fromforest soil, was grown, the acidic dye condensed around theorganism's colonies (Fig. 2A). In contrast, a basic dye, methyleneblue (0.002%), was excluded from the surrounding zone (Fig.2B). These results suggest that the substance or substancessecreted from MN-1 are basic. Such phenomena were also observedwhen ${varepsilon}$ -PL, a positively charged substance, was directly appliedto the surface of agar plates (Fig. 2C and D). Because K. kifunensestrain IFO15206 did not make the characteristic zone aroundits colonies that MN-1 did, the secretion depended on the strain.These results indicate that charged dyes are very useful forisolation of microbes excreting electrically charged substances.An acidic dye, RBBR (0.02% in the SG agar), completely inhibitedthe growth of MN-1 originating from a single cell, whereas itdid not inhibit the growth originating from a mass of cells.This phenomenon is explainable by assuming that the amount of ${varepsilon}$ -PL secreted from a mass of cells is sufficient to counteractthe toxicity of dye. To visualize the interaction between secretedsubstances and dyes, a zone of at least 5 mm in diameter foreach colony was needed. This can permit simultaneous detectionof up to 100 to 300 colonies on a single culture dish 9 cm indiameter. Based on this point, this plate-screening method issuperior to the conventional method.

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FIG. 2. Detection of secreted basic polymer on agar plate embedded with charged dyes. Areas surrounding colonies of K. kifunense strain MN-1, which extracellularlly produced poly-L-lysine, condensed acidic dye Poly R-478 (A), or excluded basic dye methylene blue (B). For comparison, K. kifunense strain IFO15206, which produces no ${varepsilon}$ -PL, was set as patch inoculation on agar plates containing Poly R-478 (C) or methylene blue (D) with strain MN-1. Authentic ${varepsilon}$ -PL (1 mg, 10 µl) was applied on filter paper disks ( ${phi}$ , 6 mm) set on the surface of the same plates. To test an antimicrobial activity, Bacillus subtilis strain IFO3336 and Escherichia coli strain HB101 were streaked on Luria-Bertani agar plates with and without ${varepsilon}$ -PL produced by strain MN-1, as indicated in panel E. Photographs of the surface of agar plates were taken by front lighting (A, B and E) or by back lighting (C and D).

In order to define the structure of the basic substance, theproduct secreted by MN-1 was analyzed. Hydrolysis showed thatthe product in the agar matrix was a polymer exclusively composedof lysine (Fig. 3A). The linkage pattern of lysine residueswas examined according to the method of Shima and Sakai (10),in which the free amino groups of polylysine were protectedby the DNP group and then the obtained polymer was completelyhydrolyzed. TLC showed that the main spot corresponded to N-DNP-L-lysine,not to N ${varepsilon}$ -DNP-L-lysine (Fig. 3B). Minor spots also appeared becausethe sample was a mixture of authentic ${varepsilon}$ -PL and its natural derivativesas described below. Thus, the basic substance secreted by MN-1was identified as polylysine linked by the ${varepsilon}$ -amide bond, namely, ${varepsilon}$ -PL. This polymer had the same antimicrobial activity as thatshown in the conventional experiments (Fig. 2E).

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FIG. 3. TLC of ${varepsilon}$ -PL produced by K. kifunense strain MN-1. (A) Lanes: 1, L-lysine (1 µg); 2 and 3, heat-treated polymers in the presence of 1 or 6 N HCl, respectively; 4 and 5, heat-treated blank agar pieces (1 or 6 N HCl). (B) Hydrolysate of DNP-protected polymer. Lanes: 1, L-lysine (1 µg); 2, N,N'-di(2, 4-DNP)-L-lysine (10 µg); 3, N-2,4-DNP-L-lysine (10 µg); 4, hydrolysate of DNP-protected polymer produced by MN-1; 5, N-2,4-DNP-L-lysine (10 µg).

Distribution of ${varepsilon}$ -PL-producing microorganisms.
The method presented here enabled screening of a large numberof microbes. We carried out careful and extensive screeningof soil microflora. After exhaustive screenings of 300 soilsamples, more than 10 ${varepsilon}$ -PL producers were isolated. All of thepolymers secreted by the representative four isolates had beenconfirmed to be composed of a lysine monomer (Fig. 4A). Similardata (not shown) were generated for the remaining isolates.The frequent isolation of ${varepsilon}$ -PL producers suggested that productionof ${varepsilon}$ -PL is not a unique activity of soil microbes. Based on the16S ribosomal DNA (rDNA) sequencing data, all bacterial isolateswere shown to belong to the genera of Streptomyces and its relative,Kitasatospora (Fig. 5). The distribution of ${varepsilon}$ -PL-producing bacteriawas limited within one family, Streptomycetaceae, but they werewidely distributed over its genera. By the same method, an ergotfungus producing ${varepsilon}$ -PL, Epichloe sp. strain MN-9, was isolatedand found to be evolutionally distant from Streptomycetaceae.MS of the fungal ${varepsilon}$ -PL is shown in Fig. 8A

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FIG. 4. Variation in molecular masses among ${varepsilon}$ -PL-producing isolates. (A) TLC of the complete hydrolysates from ${varepsilon}$ -PL polymers. Arg, L-arginine (1 µg); Lys, L-lysine (1 µg). Lanes: 1 to 5, hydrolysate of agar pieces from strains MN-1, MN-6, MN-4 (from a zone proximal to a colony), MN-4 (from a zone distal to a colony), and MN-10, respectively; Blank, agar pieces from a blank area. (B) SDS-PAGE of uncut ${varepsilon}$ -PL polymers. M, size marker; S, commercially supplied ${varepsilon}$ -PL. Lanes 1 to 5 are the same as in panel A. Molecular masses determined by MALDI-TOF MS are indicated on top. Note that polymers of ${varepsilon}$ -PL do not fit the calibration with standard molecular mass markers.

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FIG. 5. Distribution of the ${varepsilon}$ -PL-producing filamentous bacteria. Strains in boxes are the ${varepsilon}$ -PL producers isolated by the present method. The phylogenetic relationship was drawn in a neighbor-joining tree based on the 16S rRNA sequence. Some representative species in taxonomic clustering (14) are also shown for convenience of explanation.

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FIG. 8. MALDI-TOF MS of ${varepsilon}$ -PL and its derivatives produced by a bacterium, K. kifunense strain MN-1, and an ergot fungus, Epichloe sp. strain MN-9. (A) Comparison of mass spectra among samples of secretions by MN-1 and MN-9 and authentic ${varepsilon}$ -PL. The values of n indicate the numbers of lysine residues. (B) Magnified mass spectrum of MN-1 from the same measurement as in panel A (upper). Peaks representing authentic ${varepsilon}$ -PL polymers are noted by m/z values and the numbers of lysine residues (n). Peaks for derivative polymers are marked by asterisks.

Qualitative variation of ${varepsilon}$ -PL among isolates.
Our method carried out on an agar plate directly indicated boththe density and diameter of the concentric zone of secretion.Although the phylogenetic study concluded that all of the isolateswere very closely related bacteria, the density and diameterof the concentric zone of secretion depended on the individualisolate. The density reflected the amount of polymer produced,which was determined by the productivity of an isolate (datanot shown). On the other hand, the diameter reflected the diffusiveness,which was expected to be partly determined by the molecularmass of the polymer. While each of the ${varepsilon}$ -PL-producing isolateshad a particular size in terms of the concentric zone of secretion,S. albulus strain MN-4 produced at least two kinds of secretionzones (Fig. 6A). They were called "distal" for the outside zoneand "proximal" for the inside one. K. kifunense strain MN-1showed similar concentric zones, but they were not as clearlyseparated as those of MN-4. Streptomyces roseoverticillatusstrain MN-10 was unique in that the secretion zone was limitedto only around the colony. The time course of the increase inthe size was determined by measuring the distance between themargin of diffusion and the margin of a colony (Fig. 6B). Thetime course was almost linear for the zones of all strains,except for the proximal zone of MN-4. The nonlinearity was likelycaused by the proximal zone that spread into the distal zonecomposed of a rapidly diffusing ${varepsilon}$ -PL polymer. The diffusion velocitiesof strains MN-4 (distal), MN-1, and MN-6 were about 2.5, 1.3,and 0.9 mm per day, respectively. Secretion by MN-10 was notobserved within 8 days (Fig. 6A), but the diffusion velocitywas less than 0.1 mm per day after prolonged cultivation.

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FIG. 6. Diffusion of ${varepsilon}$ -PL on an agar plate. (A) Diffusion of secreted PL polymers into agar matrix. Seed cultures were inoculated by patch setting on the SG agar medium containing methylene blue. (B) The diffusion distance is the distance between the margin of the concentric zone of secretion and the margin of a colony. The diffusion distance was measured when ${varepsilon}$ -PL producers grew on GS medium containing Poly R-478. Values are means ± standard deviations (n = 3).

In order to examine whether the diffusion velocity was correlatedwith the molecular weight distribution, ${varepsilon}$ -PL polymers were recoveredfrom the concentric zones of secretion, and their molecularmasses were measured by SDS-PAGE (Fig. 4B). From strain MN-4,in particular, two kinds of secretion products were separatelyrecovered from the proximal and distal zones. The molecularweight distribution varied among isolates. Based on the calibrationgenerated from data obtained by MALDI-TOF MS, the molecularmasses of ${varepsilon}$ -PL produced by MN-1, MN-6, MN-4 (distal), MN-4 (proximal),and MN-10 were estimated to be about 1.6, 1.9, 0.8, 2.0, and0.9 kDa, respectively. As shown in Fig. 7, there was a negativecorrelation (r² > 0.99940) between the diffusion velocityand the molecular weight. However, for strain MN-10, such acorrelation was not observed. Therefore, this correlation wasapplicable to the ${varepsilon}$ -PL polymer with a nonderivatized structurein order to estimate the molecular mass from the diffusion velocity.

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FIG. 7. Correlation between the molecular mass of polymer and the diffusion velocity.

Discovering novel ${varepsilon}$ -PL derivatives.
Among our isolates, there were a few particular strains, suchas MN-10, which departed from the correlation, and MN-1, whichproduced a mixture of unknown polymers. Their products wereshown to be essentially composed of a lysine monomer by TLCanalysis of the hydrolysate (Fig. 4A). However, a question aroseas to whether the native structure of the polymers remainedafter moderate acid hydrolysis (1 N HCl, 100°C, 1 h), becausesuch a treatment might destroy modifications such as acyl substitutionson lysine residues. To answer this question, unknown polymerswere extracted by electroelution and then subjected to MALDI-TOFMS. Unfortunately, we could not obtain the MS data for strainMN-10, and only those for strain MN-1 were obtained (Fig. 8).Since ${varepsilon}$ -PL is a chain of lysine residues (molecular weight, 146.19)linked by dehydration of water (molecular weight, 18.02), itsmolecular weight should be calculated based on the formula 146.19x n - 18.02 x (n - 1), where n is the number of lysine residues.The polymers produced by MN-1 had a series of (M+H)⁺ valuesthat fit the formula. For example, the signal at 1430.8 wasnearly consistent with the value obtained by substituting 11for n in the formula. It was a signal from an ${varepsilon}$ -PL undecamer.The molecular mass distribution ranged from 1.2 to 2.1 kDa.In addition, MN-1 also had a series of (M+H)⁺ values that increasedby about 74 or other constants from the original values. Theseadditional peaks were not detected in both MS on authentic ${varepsilon}$ -PLand secretion by a fungus strain, MN-9 (Fig. 8A). Although theactual increment was not determined only from the mass spectra,it was noteworthy that an interval of about 128 was conservedamong a series of signals. This means that only one residue,probably either an N- or C-terminal lysine residue, was chemicallymodified. Thus, MN-1 produces a derivative of ${varepsilon}$ -PL in additionto the original structure.

DISCUSSION

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Discussion

Our improved method has the following three advantages. (i)It can sensitively find ${varepsilon}$ -PL producers. It is based on the strongelectrostatic interaction between ${varepsilon}$ -PL and charged dyes. Generally,dyes with an anthraquinone structure are toxic to microbialcells. The acidic dye, Poly R-478, exhibits relatively low toxicity,because the anthrapyridone chromophore is linked to a poly(vinylamine)backbone that is too large to enter the cells (molecular weight,>40,000). Consequently, Poly R-478 is effective in detectingan ${varepsilon}$ -PL producer, even if it secretes only a small amount ofpolymer. The method is also effective in selecting ${varepsilon}$ -PL producerswith high productivity of a charged polymer. A smaller acidicdye, RBBR (molecular weight, 626.6), inhibited cell growth,but its toxicity was counteracted by the secretion of a certainamount of ${varepsilon}$ -PL. Therefore, controlling the concentration of toxicdyes might enable discrimination of ${varepsilon}$ -PL producers with highproductivity from other microbes. In principle, the presentmethod is also applicable to the screening of oppositely chargedsubstances, such as acidic polypeptides. (ii) It is applicableto solid culture media in which a large number of microbes canbe screened. This simple and sensitive method enabled us toexhaustively screen the soil microflora. (iii) It can provideinformation about the amount and molecular weight of the secreted ${varepsilon}$ -PL. The molecular weight of a polymer can be estimated fromits correlation with the diffusion velocity of the polymer.The correlation covers a molecular mass range of about 0.5 to2.5 kDa. For polymers longer than 2.5 kDa, it is necessary tochange the solidifying agent to allow their diffusion.

By using the newly developed method, we carried out an exhaustivescreening of soil microflora. Surprisingly, the distributionof ${varepsilon}$ -PL producers was quite limited among bacteria in the familyStreptomycetaceae and ergot fungi, among which the relevantgenes might transfer horizontally. It cannot be completely deniedthat the culture conditions are suited for preferentially isolatingmembers of Streptomycetaceae and ergot fungi. However, the screeningmethod should be applicable to almost all of the neutrophilicand mesophilic microbes, because the culture conditions aregenerally applicable to the screening of most general microbes.It is very interesting to note that the evolutionally distantgroups bacteria and fungi commonly produce ${varepsilon}$ -PL. To prove thepossibility of the transkingdom genetic transfer, further investigationsare required.

In spite of the limited distribution, there are structural differences,particularly in terms of molecular weight. It is possible thatthe genes relevant to the control of molecular weight were modifiedafter their putative gene transfer, because the differencesare not closely related to the phylogenetic position of theproducers. In analogy to the synthesis of poly(glutamic acid),which is coded only by three genes (1, 8), it is possible that ${varepsilon}$ -PL synthesis is controlled by one or a few genes. Our resultssuggest that a relatively minor genetic alteration occurredin ${varepsilon}$ -PL producers, causing the variation in molecular weightof the polymers.

This is the first report on the chemically modified ${varepsilon}$ -PL derivatives.Very little is known about the mechanism underlying the antimicrobialactivity of ${varepsilon}$ -PL. It seems plausible that the positively chargedportions initially bind to negatively charged components ofthe cell membrane, such as phosphatidylglycerol and cardiolipin.Such a model explaining the initial stage of the antimicrobialactivity was proposed for natural polycationic antibiotic peptides,such as nisin, magainin, and defensin (2, 3, 9). The increasein hydrophobic interaction besides the electrostatic one maystabilize the binding between the membrane and ${varepsilon}$ -PL, which isexpected to intensify the antimicrobial activity. Because hydrophobicitymay influence the diffusiveness, the improved method describedhere should contribute toward finding ${varepsilon}$ -PL derivatives whichhave hydrophobicity different from that of the original ${varepsilon}$ -PL.The screening, which focused on filamentous bacteria and fungi,will be essential for finding microbes suitable for industrialapplications, in view of the limited distribution of ${varepsilon}$ -PL-producingmicrobes.

ACKNOWLEDGMENTS

We are grateful to M. Iwabuchi (RIBS) for helpful discussions.

FOOTNOTES

* Corresponding author. Mailing address: Research Institute for Biological Sciences Okayama (RIBS), 7549-1 Kayo-cho, Okayama 716-1241, Japan. Phone: 81-866-56-9452. Fax: 81-866-56-9454. E-mail: mnishikawa{at}bio-ribs.com.

REFERENCES

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