Introduction
Fermented Kimchi is a traditional food of South Korea made of mixtures of natural materials containing diverse bioactive substances. Fermented Kimchi is prepared by salting Chinese cabbage (main material) and other vegetables followed by mixing with spices and fermenting the mixture [5]. The types of fermented Kimchi vary depending upon the types of vegetables (Chinese cabbage, Chinese radish, radish, cucumber, etc.) and spices (red pepper, scallion, garlic, ginger, onion, sesame seeds, marine products, etc.) used. Fermented Kimchi is rich in vitamins, dietary fibers, and lactic acid bacteria (LAB). In addition, since fermented kimchi has excellent anti-cancer, anti-oxidative, anti-arteriosclerosis, and anti-obesity effects, it was selected as one of five best health foods in the world in 2006 by Health Magazine [3, 4, 29, 30, 32].
Chitosan is a natural biopolymer made from crustaceans such as crabs and shrimps. It has antimicrobial, anticancer, and immune modulation effects [35, 41]. It is in the β-1,4 bound structure of N-acetyl-D-glucosamine, is not digested in the small intestine of human bodies due to the lack of the digestive enzyme, but is fermented by microbes in the large intestine [8]. The addition of chitosan to kimchi fermentation inhibits the growth of Lactobacillus plantarum and Leuconostoc mesenteroides, thus extending the maturation and preservation period of kimchi [27, 41].
It is well established fact that the intestinal microbiota affects nutrition, growth, and metabolic processes through interactions with the host, and is associated with the onset of metabolic diseases such as obesity, arteriosclerosis, and diabetes [11]. In addition, intestinal microbiota affects the host’s immune responses [12, 38]. There are a number of factors that affect composition and structure of intestinal microbiota including food, age, and antibiotics; while the effects of food are most significant among them [10, 22, 39].
Researches on fermented Kimchi conducted so far have mostly focused on bioactive actions of fermented Kimchi on the host, and in changes of the fermenting microbes during the process of Kimchi fermentation [1, 23, 28]. However, the study focused on the changes in intestinal microbiota depending on intake of fermented Kimchi remains to be discovered. In our previous study, the changes in intestinal microbiota after fermented Kimchi intake for one week in adult females were investigated. However, due to the short experimental period and inter-individual differences, the results remain to be further studied [13]. The present experiment was conducted using rats as experimental animals in order to characterize the effects of fermented Kimchi (FK) and chitosan-added fermented Kimchi (CFK) on the host response (body weight, feed intake and adiposity indices) as well as the composition and structure of intestinal microbiota.
Materials and Methods
Feed and experimental animal
Fermented Kimchi made by Unlimga Co. (Gwangju, Korea) and chitosan with the molecular weight of 3,500 (Kitto Life, Pyeongtaek, Korea) were used for the preparation of experimental diets. The fermented Kimchi was matured for 12 days at 4℃ and the chitosan-added fermented Kimchi was prepared by adding 1 g of chitosan per 100 g of Chinese cabbage with spices. The chitosan-added fermented Kimchi was matured for 30 days at 4℃ before being used in the experiment. Since chitosan slows down the progression of the fermentation of Kimchi, the fermented Kimchi was matured for 12 days, whereas the chitosan-added fermented Kimchi was matured for 30 days at 4℃[27]. Each fermented Kimchi was freeze-dried, mixed with the basal diet for rat, made into pellets, and then supplied to the experimental animals. The quantity of the fermented Kimchi added to the basal diet was determined according to the daily intake of Kimchi per South Korean adult (100 g for an adult of average body weight 60 kg).
Forty-five male Sprague-Dawley rats of six weeks old were purchased from Samtako (Osan, Korea). With five repetitions of three per cage per group, the experimental animals were divided into three treatment groups that received either basal diet (CON), basal diet supplemented with fermented Kimchi (FK) or chitosan-added fermented Kimchi (CFK) for 4 weeks. The experimental animals were maintained in the controlled environment with 20~25℃ temperature, 50~60% humidity, and 12/12 hr cycle of day/night. Feed and water were provided ad libitum. The body weights and feed intakes of the experimental animals were measured once per week during experimental period. The experimental animals were anesthetized after finishing experiment, and their blood was collected to measure blood lipid concentrations. All the animal experimental procedures were approved by the Institutional Animal Care and Use Committees at Gyeongnam National University of Science and Technology (Approval No. 2015-1).
PCR of 16S rRNA genes
The intestinal contents from small intestine, cecum, and large intestine of the experimental animals were collected at the end of the experiment. The contents from the 3 regions were combined for each animal, which was then used to extract genomic DNA using ZR Fecal DNA MiniPrepTM (Zymo Research, USA). Microbiome analysis was conducted through pyrosequencing of the 16S ribosomal RNA (rRNA) genes through ChunLab (Seoul, Korea). Briefly, V1-V3 regions of the 16S rRNA gene was amplified from the genomic DNA samples using primers and PCR conditions as described previously [13]. The PCR products were purified using a QIAquick PCR purification kit (Qiagen, Valencia, CA, USA) and quantified using a PicoGreen dsDNA Assay kit (Invitrogen, Carlsbad, CA, USA). The amplicons of individual samples in equimolar concentrations were pooled, and sequenced using the Roche/454 FLX system.
Pyrosequencing analysis
The pyrosequencing data of the 16S rRNA gene sequences were processed using the Java-based multi-step bioinformatics pipeline. Unidirectional sequencing reads were distinguished based on the unique barcodes of individual reads. Low-quality sequences shorter than 300 bp were removed from the reads using TBC clustering algorithm [19]. Trimmed sequencing reads were clustered into the sequences with the similarity of 97% or higher [19] to identify operational taxonomic units (OTUs). Representative sequences were selected from the clusters of trimmed sequences for identification of the associated taxonomic groups. Taxonomy was determined for representative sequences by the highest similarities among the top five BLASTN hits in the EzTaxone database [14]. The sequences in the EzTaxone database that were not identified in the BLASTN searches were classified as non-target sequences and thus were excluded from the further analysis. The similarity of base sequences between the query and candidate species was calculated using the Myers and Miller method [24]. The cladogram was calculated using the TBC clustering algorithm [19]. Overall phylogenetic differences, Shannon index, and heat map analyses of the correlations across three different groups were investigated using the CL community program provided by ChunLab (Seoul, Korea).
Statistical analysis
The statistical analysis of the data was performed using the General Linear Model (GLM) procedure of the SAS (Version 9.1). The pairwise comparison among different groups was performed by Tukey’s multiple range tests where the level of significant was considered at 0.05 (p<0.05) unless described otherwise.
Results
Weight gains and feed efficiency
The total body weight gain and average daily body weight gain decreased in both FK and CFK as compared to the control, although the observed differences were not significant (Fig. 1A, Fig. 1C). On the contrary, the total feed intake increased in both FK and CFK as compared to the control, while the increase was significant only for FK (Fig. 1B). The feed efficiency decreased significantly by both FK and CFK groups as compared to the control (Fig. 1D). These results suggest that the supply of the fermented Kimchi or chitosan-added fermented Kimchi effectively suppressed the body weight gain.
Fig. 1. The effects of the consumption of the diets supplemented with fermented kimchi (FK) and chitosan-added fermented kimchi (CFK) in comparison to the basal diet group (CON) on (A) body weight gain, (B) total feed intake, (C) average daily body weight gain, and (D) feed efficiency of the Sprague-Dawley rats. *; p<0.05.
Serum lipid concentration
To investigate the effects of the consumption of the fermented Kimchi on the body fat formation, the concentrations of the blood lipid components including low-density lipoprotein (LDL) cholesterol, high-density lipoprotein (HDL) cholesterol, and triglycerides were measured. After feeding for 4 weeks, there was no significant difference in serum LDL and HDL cholesterol concentrations among the control, FK, and CFK groups (Fig. 2A, Fig. 2B), but it were higher than that of the control group. However, triglycerides concentrations of FK and CFK groups were 73 mg/dl and 71 mg/dl, respectively, which were significantly lower as compared to the control group (136 mg/dl) (Fig. 2C; p<0.01). But there was no significant difference in serum triglycerides concentration between FK and CFK groups. The decrease in serum triglycerides concentrations in both FK and CFK groups show that the fermented Kimchi can suppress body fat accumulation.
Fig. 2. Effects of the consumption of the diets supplemented with the fermented kimchi (FK) and chitosan-added fermented kimchi (CFK) on fat metabolism of the Sprague-Dawley rats in comparison to the basal diet group (CON). (A) LDL cholesterol, (B) HDL cholesterol, and (C) triglyceride. **; p<0.01.
Intestinal microbiota analysis
To investigate the effects of fermented Kimchi on the composition and structure of intestinal microbiota, FK and CFK were fed to the experimental rats for 4 weeks. The collected intestinal contents were combined for each rat, and the PCR products of 16S rRNA genes amplified from the samples were used to analyze the intestinal microbiota through pyrosequencing and bioinformatics analysis. The intestinal bacterial composition at different taxonomic levels was summarized in Table 1. At the phylum level, nine phyla that are common members of rats’ intestine were found across all three treatment groups (Fig. 3A). Among the nine phyla, Firmicutes and Bacteroidetes were the two dominant phyla that accounted for 92.9% (CON), 94.4% (FK), and 93.9% (CFK) of total intestinal microbiota (Fig. 3B). The ratio of Bacteroidetes to Firmicutes, which has been shown to correlate with the obesity, increased in FK and CFK as compared to the control (Fig. 3B). As indicated in the heat map showing relative abundance of different phyla (Fig. 4), FK and CFK groups were clustered together in comparison to the control group, suggesting that the intestinal microbiota was shifted to form similar microbial communities by the intake of FK and CFK.
Table 1. The number of different taxonomic groups at different levels of hierarchical classification in the intestinal microbiota of the Sprague-Dawley rats fed with the basal diet (CON), the basal diet with supplemented fermented kimchi (FK) or chitosan-added fermented kimchi (CFK)
Fig. 3. The relative abundance of different phyla in the intestinal microbiota of the Sprague-Dawley rats fed with the basal diet (CON), the basal diet with supplemented fermented kimchi (FK) or chitosan-added fermented kimchi (CFK). (A) Bar graph showing the relative abundance of 9 phyla, and (B) Pie graph showing only two dominant phyla, Firmicutes and Bacteriodetes, highlighting the changes in the ratio of the two phyla in FK and CFK in comparison to CON.
At the genus level, altogether 234, 243, and 250 different genera were found in CON, FK, and CFK groups, respectively (Table 1). To understand the functional capacities associated with the changes in intestinal microbiota, the distribution of intestinal microbiota was classified into functional microbial groups of LAB, leanness-associated bacteria, and butyric acid-producing bacteria where the abundance for each of these microbial groups was indicated with the combined number of sequence reads of the corresponding OTUs (Table 2). Regarding LAB, the two genera (Lactobacillus, and Streptococcus) were present in the control, FK, and CFK groups, while two additional genera (Bifidobacterium, and Leuconostoc) were present in CFK group. In all three groups, Lactobacillus, Prevotella, Alistipes, and Butyricicoccus were dominant genera. The total portion of LAB was higher in FK and CFK groups as compared to the control group. Moreover, the abundance of LAB in CFK group was nearly two folds higher than the control group. Among the leanness-associated bacterial genera, Prevotella, Alistipes, and Bacteroides were commonly found in all three treatment groups, with Prevotella being a dominant genus. Leanness-associated bacteria increased by at least 30% in FK and CFK groups, as compared to the control group. Among the butyric acid-producing bacteria, Roseburia and Butyricoccus were commonly present in all three treatment groups and was 2.6 and 1.8 times higher in FK and CFK groups, respectively, in comparison to the control group. Clustering analysis of the relative abundance of these functional bacterial groups indicated that FK and CFK groups were clustered together in reference to the control group as shown in the heat map (Fig. 5). The heat map also shows the overall trend that these three functional bacterial groups including LAB, leanness-associated bacteria, and butyric acid-producing bacteria increased by consumption of FK and CFK as compared to the control group.
At species level, 546, 549, and 579 different bacterial species were identified in CON, FK, and CFK groups, respectively (Table 1). In addition, more diverse taxa were recovered from the treated groups as compared to the control at all levels except the phylum. Shannon index was used to measure the alpha diversity whose mean values were 5.88, 6.17, and 6.36 in CON, FK, and CFK groups, respectively. Thus, as compared to the control group, both treatment groups (FK and CFK) showed more diverse microbial communities (Table 1).
Table 2. Relative abundance of the functional bacterial groups in the intestinal microbiota of the Sprague-Dawley rats fed with the basal diet (CON), the basal diet with supplemented fermented kimchi (FK) or chitosan-added fermented kimchi (CFK)
Fig. 4. Heat map showing the relative abundance of 9 phyla in the intestinal microbiota of the Sprague-Dawley rats fed with the basal diet (CON), the basal diet with supplemented fermented kimchi (FK) or chitosan-added fermented kimchi (CFK). Clustering based on the abundance profile is shown on the top of the heat map.
Fig. 5. Heat map showing the relative abundance of genera according to the functional microbial groups in the intestinal microbiota of the Sprague-Dawley rats fed with the basal diet (CON), the basal diet with supplemented fermented kimchi (FK) or chitosan-added fermented kimchi (CFK). Clustering based on the abundance profile is shown on the top of the heat map.
Discussion
Although fermented Kimchi which is rich in dietary fibers and LAB was evaluated to improve host’s health, available researches on the effects of the fermented Kimchi consumption on intestinal microbiota are insufficient. In our previous study, an experiment was conducted with South Korean adult females to examine the changes in intestinal microbiota following fermented Kimchi consumption for one week [13]. According to the results of the study, intestinal microorganisms beneficial for the host’s health were increased with the intake of fermented Kimchi. However, due to the short diet period of fermented Kimchi during previous study, it’s difficult to conclude that the intestinal microorganisms settled down stably. During studying by other group where fermented Kimchi was supplied for eight weeks, the composition of intestinal microbiota was clearly different between the first and the eighth week of consumption [9]. In another study that focused on the intestinal microbiota transplantation, the composition of gut microbiota was examined for 4 weeks after transplantation [39]. Thus, the question remained whether the fermented Kimchi intake for one week in our previous experiment was sufficient for intestinal microbes to settle down for the stable intestinal microbiota formation [13]. In addition, although beneficial intestinal bacteria including LAB were significantly increased in the fermented Kimchi groups as compared to the control, there were substancial inter-individual differences within the same treatment group. To solve these problems, in the present study, a feeding period of four weeks was used so that the intestinal microbiota could be stabilized in experimental animals and reduce inter-individual variations. In addition, the effects of chitosan-added fermented Kimchi on intestinal microbes were also examined.
In the present study, after supplying fermented Kimchi or chitosan-added fermented Kimchi for four weeks, the total body weight gain, daily weight gain, total feed intake, and feed efficiency of the experimental animals were measured to investigate the weight gain efficiency of the experimental animals (Fig. 1). Although, as compared to the control group, FK and CFK groups showed tendencies towards decrease in total body weight gain and daily weight gain, and increase in total feed intake, no significant difference was found across the 3 groups (Fig. 1A, Fig. 1B, Fig. 1C). However, the feed efficiency of FK and CFK groups was lower than that of the control group (Fig. 1D). A lower feed efficiency means smaller body weight gain when the same quantity of food is taken. The fact that the fermented Kimchi intake is effective for the suppression of body weight gains is well known. In particular, fermented Kimchi shows the effect of reducing blood triglyceride concentrations and suppressing body fat accumulation [4, 29]. The effect to suppress body fat is due to the dietary fiber and the capsaicin present in the ingredients of Fermented Kimchi. The major ingredient of Fermented Kimchi is Chinese cabbage which is rich in dietary fibers [13]. Water-soluble and viscous dietary fibers increase satiety and lead to decrease in food intake and nutrient absorption in the small intestine [37]. Dietary fibers produce short chain fatty acids (SCFAs) through mi crobial fermentation in the large intestine and among the SCFAs; butyric acid suppresses fat accumulation [21]. The capsaicin in red pepper that makes the spicy taste of fermented Kimchi stimulates the adrenal sympathetic nerves to increase the secretion of adrenalin, thereby promoting the decomposition and combustion of body fat [2, 16].
Fermented Kimchi reduces plasma triglyceride and LDL cholesterol concentrations, while increasing HDL cholesterol concentrations [17]. However, in the present experiment, no difference in the blood concentrations of LDL- and HDL-cholesterol between the treatments with fermented Kimchi and with chitosan-added fermented Kimchi was observed (Fig. 2A, Fig. 2B). These differences in the experimental results can be attributed to the differences in experimental conditions such as the quantity of supplied fermented Kimchi, feeding period, and high fat diet vs. basal diet. Plasma triglyceride concentrations were shown to be lower in the animals supplied with fermented Kimchi or chitosan-added fermented Kimchi (Fig. 2C). Plasma triglyceride concentrations are closely related to abdominal obesity [7]. Therefore, the supply of fermented Kimchi may suppress obesity by reducing plasma triglyceride concentrations.
When high-fat and high-sugar diet, and standard low-fat and high-polysaccharide diet were fed to the mice, those mice taking standard low-fat, high-polysaccharide diet showed a higher diversity of intestinal microbes [39]. This diversity of microorganisms in intestinal microbiota was shown to be closely related to the suppression of obesity. In the present study, when fermented Kimchi or chitosan-added fermented Kimchi was supplied to rats, the rats showed more diverse species of intestinal microorganisms than the animals supplied with the control diet (Table 1).
When intestinal microorganisms from obese mice were transplanted to germfree mice, the recipient showed remarkable increase in fat accumulation that promotes obesity [39]. The Firmicutes and Bacteroidetes are dominant bacterial phyla in human intestine and were shown to be associated with obese and lean body types, respectively [34]. Thus, increase in Firmicutes and Bacteroidetes in the intestine promotes obesity and leanness, respectively. In our study, the Firmicutes and Bacteroidetes were found to be dominant bacterial phyla in all treatment groups, and accounted for at least 92% of all intestinal bacteria (Fig. 3A). The supply of fermented Kimchi and chitosan-added fermented Kimchi increased Bacteroidetes and reduced Firmicutes as shown in Fig. 3. This shift in intestinal microbiota in comparison to the control group was similarly observed in both FK and CFK groups as demonstrated in the heat map (Fig. 4). Hence, the intake of fermented Kimchi or chitosan fermented Kimchi promoted the abundance of intestinal bacterial phyla that can suppress the obesity.
LAB affect the immune modulation by secreting bacteriocins which are natural antibiotics that suppress the growth of harmful bacteria, and by promoting the secretion of IgA and gamma-interferon in blood [36]. In addition, Bifidobacterium longum and Lactobacillus acidophilus reduce the total and LDL cholesterol without changing the concentration of HDL cholesterol [31]. For this reason, Bifidobacterium, Lactobacillus, Lactococcus, Leuconostoc, and Streptococcus are often used commercially as probiotics. At the genus-level, as compared to the control group, LAB increased in the groups treated with fermented Kimchi and chitosan-added fermented Kimchi (Table 2). Chitosan is a prebiotic that promotes the growth of intestinal Bifdobacterium and Lactobacillus [18]. Chitosan-added fermented Kimchi group had at least four times more Lactobacillus than the control group or the fermented Kimchi group and showed Bifidobacterium that did not exist in other treatment groups (Table 2).
The increase in LAB following treatments in the present experiment can be attributed to the dietary fibers and chitosan in fermented Kimchi. Prevotella, Alistipes, and Bacteroides are a group of intestinal bacteria that can suppress obesity and present more in lean persons [6, 25]. Higher intestinal abundance of Provotella in mice were correlated with decrease in fat accumulation [26]. These leanness-associated bacteria especially Prevotella increased with the supply of fermented Kimchi and chitosan-added fermented Kimchi (Table 2). Indigestible polysaccharides form SCFAs such as acetic acid, propionic acid, and butyric acid through the process of fermentation by intestinal microbes [40]. Butyric acid which is absorbed into blood steam promotes the decomposition of fat into fat cells and regulates the actions of gut hormones and insulin to suppress fat accumulation [15, 20, 33]. Thus, the increase in butyric acid-producing bacteria in the present study might be responsible for the reduction of blood triglycerides concentrations.
The supply of fermented Kimchi and chitosan-added fermented Kimchi reduced feed efficiency and blood triglyceride concentrations. In addition, it promoted the diversity of intestinal microorganisms and increased the abundance of LAB, leanness associated and butyric acid-producing bacteria. Furthermore, LAB increased the most by supple mentation of the chitosan-added fermented Kimchi in addition with Bifidobacterim. Therefore, the results of the present study support the hypothesis that fermented Kimchi and chitosan-added fermented Kimchi can suppress obesity through mechanism(s) that might involve the modulation of the intestinal microbiota.
Acknowlegements
This research was financially supported by the Ministry of Knowledge Economy (MKE), Korea Insitute for Advancement of Technology (KIAT) and Honam Leading Industry Office through the Leading Industry Development for Economic Region, and funded by a grant funding from the Gyeongnam National University of Science and Technology in 2018.
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