ABSTRACT
Young watermelon fruit was peeled and pickled for fermentation to produce a unique fermented food named xi-gua-mian (fermented watermelon) in Taiwan. In this study, we investigated the LAB microflora in xi-gua-mian. A total of 176 LAB isolates were identified; 118 cultures were isolated from the xi-gua-mian sample collected from three different farmers markets and 58 from six young watermelon fruit samples. These isolates were characterized phenotypically and then divided into seven groups (A to G) by restriction fragment length polymorphism analysis, sequencing of 16S ribosomal DNA and other genotypic analysis. Lactobacillus plantarum was the most abundant LAB found in xi-gua-mian samples collected in southern Taiwan, Tainan City and Pediococcus pentosaceus was the most abundant LAB in northern Taiwan, Taoyuan County. We found that LAB stains are similar in samples collected in the same geographic region but significant variations were observed between samples collected among different regions. On the other hand, a greater LAB diversity was observed in the young watermelon fruit samples. In addition, 10 Lactococcus lactis subsp. lactis showed inhibitory activity against the indicator strain L. sakei subsp. sakei JCM 1157T. This is the first report describing the distribution and varieties of LAB existing in the xi-gua-mian and the young watermelon fruits.
- Keywords: lactic acid bacteria, xi-gua-mian, fermented watermelon, Taiwan -
INTRODUCTION
Watermelon (Citrullus lanatus) is a popular fruit in Taiwan. The farming area dedicated to watermelon production in Taiwan is reported to be largest among all fruits (LIN et al, 2009). To have a better harvest, surplus fruits are eliminated and only one fruit is retained for every stock in the early phase of watermelon cultivation. In Taiwan, farmers use the eliminated young watermelon fruits to produce a unique fermented food named xi-gua-mian (fermented watermelon).
These immature watermelon fruits are peeled, cut, mixed with salt (NaCl) and then placed in a bucket. Salt is added to a final concentration of approximately 3-6%, and the bucket is sealed with heavy stones placed on the top of the cover. This process usually continues for 3 days and then the exuded water is drained. The bucket is sealed again with heavy stones and the fermentation process continues for at least 2 weeks at room temperature. Because of the contribution of the lactic acid bacteria (LAB), it has a special sour and sweet flavor. Xi-gua-mian is usually applied as a seasoning for various pork, seafood and poultry dishes in order to add a slightly acidic taste. Although the product is very popular, it has not been studied in detail.
Lactic acid bacteria (LAB) has been frequently found in various Taiwanese fermented foods such as yan-tsai-shin (fermented broccoli stems), yan-jiang (fermented ginger), jiang-sun (fermented bamboo shoot), suan-tsai (fermented mustard), dochi (fermented black beans), jiang-gua (fermented cucumbers), yan-dong-gua (fermented wax gourd) and pobuzihi (fermented cummingcordia) (CHANG et al, 2011; CHEN et al, 2006a, 2006b, 2010, 2012, 2013a, 2013b; LAN et al, 2009). In these cited studies, various LAB species, such as Enterococcus faecium, Lactobacillus plantarum, Lactococcus lactis subsp. lactis, Weissella cibaria and W. paramesenteroides, were frequently found in the Taiwanese fermented products. However, there has been very little research reported on LAB distribution in fermented watermelon (xi-gua-mian).
One important attribute of LAB is the bacteriocin-producing abilities to inhibit food spoilage bacteria and many LAB strains isolated from the Taiwanese fermented foods were found to produce various bacteriocins. Some bacteriocins produced by these strains were further identified as novel bacteriocins in the later studies such as enterocin TW21, weissellicin L and enterocin T (CHANG et al, 2013; CHEN et al ,2013c; LIANG et al, 2013).
The objectives of this study were to isolate LAB from the xi-gua-mian, to identify the isolates to the species level and to detect the antibacteri- al activities of the isolates. Our results provide an example to understand the rich resources of LAB strains in the traditional Taiwanese fermented food.
MATERIALS AND METHODS
Xi-gua-mian and the young watermelon fruit samples
A total of 3 xi-gua-mian samples (SI-S3) were collected at three traditional farmers markets located in Tainan City and Taoyuan County (Table 1, Fig. 1A). In addition, six young watermelon fruit samples (W1-W6, approximately 8-15 cm in size) were collected from Hualien County, Tainan City and Chiayi County (Table 1, Fig. IB). Samples were stored at 4°C and analyzed within 24 h of acquisition from the markets and the watermelon fields. The salt concentration and pH of xi-gua-mian juice was measured by using a model SK-5S salt meter (Sato Keiryoki, Tokyo, Japan) and a model B-l 12 compact pH meter (Horiba, Kyoto, Japan), respectively. Lactic acid in each xi-gua-mian samples was determined with a D-/L-Lactic Acid test kit (R-Biopharm AG, Darmstadt, Germany), according to the manufacturer's instructions.
Isolation of LAB
An initial analysis results showed that the xigua-mian samples SI and S2 contained 3.8 % NaCl and sample S3 contained 6 % (Table 1). Therefore, MRS agar (Difco(TM) Lactobacilli MRS Broth: Sparks, MD, USA) containing 3 % NaCl was used for the isolation of LAB from xi-gua-mian samples SI and S2. On the other hand, MRS agar containing 6 % NaCl was used for isolation from sample S3 and MRS agar without adding NaCl was used for isolation from young watermelon fruit samples. To distinguish acid-producing bacteria from other bacteria, 1% CaC03 was added to the MRS agar, and only colonies with a clear zone around them were selected (KOZAKI et al, 1992). 0.5 g of crushed young watermelon fruit samples, and 0.5-mL aliquot of each xigua-mian juice samples were taken for LAB isolation. The isolation procedures of LAB were performed according to the methods described by CHEN etal (2013a).
RFLP and sequence analysis of 16S rDNA
RFLP and sequence analysis of 16S rDNA were used to classify and identify the bacterial isolates. A colony PCR method described by SHEU et al (2000) was performed in this study. PCR reactions were carried out using a Genomics Tag gene amplification PCR kit (Genomics, Taipei, Taiwan) and performed on a Gene Amp PCR System 9700 (PerkinElmer Corp., Boston, MA, USA) under the following conditions: 95°C for 3 min, 30 cycles of 95°C for 30 s, 60°C for 30 s and 72°C for 90 s, a final extension of 72°C for 10 min, and completion at 4°C (CHEN et al, 2013b). 16S rDNA gene was amplified using the 16S rDNA universal primers 27F (5'- AGAGTTTGATCCTGGCTCAG -3j and 1492R (5'- GGTTACCTTGTTACGACTT-3j (CHEN etal, 2013b). RFLP analysis of 16S rDNA was also performed, as described by CHEN et al, (2013b). In this study, three restriction enzymes, AccII (CG/CG), Haelll (GG/CC) and Aluî (AG/CT) (Chen etal, 2013b), were mainly used for grouping. For sequence analysis of 16S rDNA, the PCR products were purified and then sequenced with the following primer: 5'-GTCAATTCCTTTGAGTTT-3' (920R). Sequence homologies were examined by comparing the obtained sequences with those in the DNA Data Bank of Japan (DDBJ; http://www. ddbj.nig.ac.jp/) using BLAST.
Differentiation of Lactobacillus plantarum, L. pentosus, and L. paraplantarum
A multiplex PCR assay with recA gene-derived primers was performed using the methods and conditions described by TORRIANI et al (2001).
Differentiation of Leuconostoc mesenteroides and Leu. pseudomesenteroides
A rapid identification method described by JANG et cd. (2003) was used to distinguish Leuconostoc mesenteroides and Leu. pseudomesenteroides isolates. Briefly, a PCR product of the isolate was amplified by using Leuconostoc-specific primers and then digested by using the restriction enzyme Tsp509l (/AATT) (JANG et al., 2003). Restriction fragments were visualized on a 2% agarose gel in lx TAE.
Differentiation of W. paramesenteroides and W. hellenica
In this study, isolate which showed high sequence homology to W. paramesenteroides and W. hellenica was further confirmed by using the restriction enzyme Hhal (GCG/C) described by CHEN et al. (2012).
Effect of NaCl on growth of isolates
Effect of NaCl on growth of isolates was assessed, as described by KOZAKI et al. (1992), by testing isolates for growth in MRS broth containing 0, 3 and 6% NaCl.
Detection of antibacterial activity
The agar well diffusion method as described by SRIONNUAL et al. (2007) was used to detect and determine the antibacterial activities of isolates. Lactobacillus sakei subsp. sakei JCM 1157Twas used as the indicator strain in this study. Antibacterial activity was further confirmed by pH adjustment and proteinase K treatment (SRIONNUAL et al, 2007).
To determine whether nisin is the antibacterial substance, a PCR assay with the nisin-specific PCR primers, NISL: 5'-CGAGCATAATAAACGGC-3' and NISR: 5'-GGATAGTATCCATGTCTGAAC-3', described by VILLANI et al. (2001), were used for amplification in this study. In addition, a nisin Z producing strain, Lc. lactis subsp. lactis CIO 1910 (YANAGIDA et al, 2006) was used as the positive control and a non-BLIS (bacteriocin-like inhibitory substance) producing strain was used as the negative control.
RESULTS
In the xi-gua-mian samples collected from different markets, analyses of xi-gua-mian juice revealed different salt concentrations from 3.8 to 6.0% and lactic acid concentrations from 35.5 to 95.0 g/L(Table 1). The average number of viable acid-producing cells was 7.36 0.18, 6.77 0.17 and 8.00 0.05 log CFU/mL from the xi-gua-mian samples SI, S2 and S3, respectively (Table 1). The detailed analysis values of each sample are shown in Table 1 and a total of 118 acid-producing bacteria were isolated from these samples.
On the other hand, a total of 58 acid-producing bacteria were isolated from the young watermelon fruit samples. The number of viable acid producing cells on the six different young watermelon fruit samples was listed in Table 1.
The total 176 isolates were initially divided into six groups (R1-R6) according to cell morphology and the results of the 16S rDNA RFLP analysis. Of these isolated strains, 85 were placed in group Rl, 40 in group R2, 20 in group R3, 4 in group R4, 3 in group R5, and 24 in group R6, according to RFLP patterns observed following digestion of their DNA with AccII, HaeIII, and AZuI. To identify the isolates, representative strains were randomly selected from each group, and 16S rDNA sequencing analysis was performed. The results identified group Rl isolates as Lactobacillus plantarum-related species, group R2 as Pediococcus pentosaceus, group R3 as Lactococcus lactis subsp. lactis, group R4 as Leuconostoc mesenteroides, group R5 as Weissella paramesenteroides, and group R6 as Enterococcus casslifiavus.
The identification of group Rl isolates was further verified using a multiplex PCR assay with recA gene-derived primers (TORRIANI et al, 2001). An expected amplification band located at 318 bp and one at 218 bp (Fig. 2, lane 1 and 2) was respectively obtained from 71 and 14 isolates. Seventy-one isolates were therefore identified as L. plantarum and re-classified into group A. The remaining 14 isolates were identified as L. pentosus and re-classified into group B. All 4 isolates in group R4 were confirmed as Leu. mesenteroides based on Tsp509l digested fragments of the PCR product of Leuconostocspecific primers and re-classified into group E (JANG etal, 2003) (Fig. 2, lane 3; Table 1). Isolates in group R5 were further verified based on Hha I digested fragments of their 16S PCR product (CHEN et al, 2012). All 3 strains were identified as W. paramesenteroides and re-classified into group F (Fig. 2, lane 4; Table 1). Following the re-classification of groups Rl, R4 and R5, isolates in the remaining groups were also reclassified with a new code. The detailed distributions of LAB species are shown in Table 1.
Effect of NaCl on growth of all 176 isolates was estimated. All P. pentosaceus, E. casslifiavus, L. plantarum, L. pentosus, W. paramesenteroides and Lc. lactis subsp. lactis isolates grew well in MRS broth containing 0, 3 and 6 % NaCl except Leu. mesenteroides isolates. Growth of Leu. mesenteroides isolates was observed neither in 3 nor 6 % NaCl MRS broth.
Ten isolated Lc. lactis subsp. lactis strains showed antibacterial activity against L. sakei subsp. sakei JCM 1157r (Table 1). The BLIS produced by all 10 strains maintained their antibacterial activities after neutralization (pH 6.5) but lost their antibacterial activities completely after treatment with proteinase K. In addition, nisin-specific primers were used to amplify a PCR fragment and identify the BLIS from these 10 strains. An expected amplification band located at 320 bp (Fig. 2, lane 5) was obtained from all Lc. lactis subsp. lactis isolates and the nisin Z producing strain, Lc. lactis subsp. lactis CIO 1910 (YANAGIDA et al, 2006). No amplification band was observed from the negative control strain.
DISCUSSION
In this study, LAB diversity in xi-gua-mian samples collected from different farmers markets and young watermelon fruits were studied. The final concentration of lactic acid and low pH values determined in the xi-gua-mian samples suggested that LAB contributed to the aroma and flavor development in xi-gua-mian.
The experimental data were treated according to critical values of Student's t-test. The viable acid-producing cell numbers between xigua-mian and fresh watermelon was significantly different (p<0.0002). We also found that the viable acid-producing cell numbers within geographical areas were different, but the statistical difference (standard deviation within xigua-mian group and fresh watermelon group was 0.61 and 0.93, respectively) was less than that between xi-gua-mian and fresh watermelon groups (4.56).
In addition, halotolerance of all isolates were assessed. All isolated strains grew well in MRS broth containing 3% and 6 % NaCl except Leu. mesenteroides isolates. Presence of NaCl in xigua-mian and isolation medium therefore might limited the growth of Leu. mesenteroides. Presence of Leu. mesenteroides was only observed in fresh watermelon fruits but not in xi-gua-mian. It is therefore considered that salt concentration has effect on diversity of LAB in the xigua-mian. Similar influence of NaCl concentrations on diversity of LAB in fermented foods has also been found in our previous studies (CHEN et al, 2006a; 2006b).
Compared to the isolation results of xi-guamian, fewer viable acid-producing cell number were observed from the young watermelon fruit samples. It is presumably because the raw material always presents a lower number or microorganisms or the absence of salt in substratum used for the isolation from young watermelon fruit samples does not allow the selection of LAB. As in the case of xi-gua-mian samples, LAB stains are similar in samples collected in the same geographic region and diversities were observed between samples collected among different regions in the young watermelon fruit samples (Table 1). Different climate conditions were considered as the main factor, which may affect the distribution of LAB.
Although xi-gua-mian samples S1 and S2 were collected at different traditional farmers markets located in Tainan City, L. plantarum and L. pentosus were the most abundant LAB found in these two samples (Table 1). Different to the isolation results obtained in the Tainan City, P. pentosaceus was the most abundant LAB found in the sample collected in Taoyuan County (Table 1). Geographically, Tainan City is located in southern part of Taiwan that belongs to the tropics, while Taoyuan County is in northern subtropical regions. It is therefore considered that regional factors, such as climate conditions, raw materials for fermentation and fermentation methods, may affect the distribution of LAB.
Lactobacillus plantarum has been identified elsewhere as one of the most abundant LAB found in several Taiwanese fermented vegetables such as fermented bamboo shoots (jiangsun), fermented cucumbers (jiang-gua), fermented broccoli stems (yan-tsai-shin) and fermented cummingcordia (pobuzihi) (CHEN et al, 2010b, 2012, 2013a, 2013b). As well as L. plantarum, P. pentosaceus also have been previously found as the most abundant LAB in the fermented mustard (suan-tsaÿ (CHEN et al., 2006a). In addition, L. plantarum was found both in the partial samples of xi-gua-mian and the young watermelon fruits. It is therefore considered that L. plantarum found in xi-gua-mian may originate from the young watermelon fruits. To clarify these points, advanced analysis on more xigua-mian and young watermelon fruit samples will be necessary in the future.
The results of the antibacterial activity assay indicated that total 10 Lc. lactis subsp. lactis isolates showed inhibitory activities against L. sakei subsp. sakei JCM 1157T. Complete inactivation of these BLIS produced by all 10 strains were observed after treating the cell-free supernatant with proteinase K, which indicates the proteinaceous nature of the active agents. When amplified with nisin-specific primers, the amplification band located at 320 bp indicated the existence of nisin-producing genes and BLIS from these 10 Lc. lactis subsp. lactis could be nisin-related variants (VILLANI et al, 2001; ZENDO et al, 2003). However, detailed information such as heat stability, their effect on enzymes, inhibition spectra, accurate molecular mass and amino acid sequences were not established in the current study.
Although LAB have been widely found in various fresh fruits, vegetables and various plant pickles, little information on the diversity of LAB associated with fermented watermelon or young watermelon fruits was obtained from previous studies. Future studies in our laboratory will characterize and identify the nisin-like BLIS, and we anticipate that the BLIS of LAB will be useful as food preservatives. The authors also hope that the results of this study can offer useful information for the improvement of xi-guamian production.
ACKNOWLEDGMENTS
The authors would like to thank the National Science Council Taiwan for financially supporting this study under Contract No. MOST 103-2313-B-130-002 and MOST 104-2320B-130-001 granted to Yi-sheng Chen.
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Paper Received September 9, 2014 Accepted February 19,2015
YI-SHENG CHEN(a) *, HUI-CHUNG WUa, CHI-RONG YU3 ZIH-YIN CHEN3 YI-CHEN LU3 and FUJITOSHI YANAGIDAb
a Department of Biotechnology, Ming Chuan University,
No. 5 De-Ming Road, Gui-Shan, Taoyuan 333, Taiwan
b The Institute of Enology and Viticulture, Yamanashi University,
1-13-1 Kitashin, Kofu, Yamanashi 400-0005, Japan
* Corresponding author: Tel. +886 33507001 ext. 3540, Fax +886 33593878,
email: [email protected]
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