JP2006056839A - Secondary bile acid production-inhibiting microorganism, and foods and drinks and animal food - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a composition which reduces the onset risk of colon cancer, liver cancer, pancreas cancer, bile duct cancer and cholelithiasis by ingestion thereof as an ordinary foods and drinks. <P>SOLUTION: The secondary bile acid inhibitor comprises bacteria belonging to the genus Ruminococcus and/or difructose dianhydride 3 (di-D-fructofuranose-1,2':2,3'-dianhydride, abbreviated as DFAIII). Foods and drinks and animal foods containing the inhibitor are also provided. The secondary bile acid inhibitor comprising raffinose, melibiose or fructooligosaccharide in addition to the combination above is also provided. Foods and drinks and animal foods containing the inhibitor are also provided. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to foods and drinks, animal feeds and materials thereof that reduce the risk of diseases such as colorectal cancer, liver cancer, and cholelithiasis by suppressing the production of secondary bile acids in the intestinal tract.

  Bile acids are made in the liver. That is, cholic acid and chenodeoxycholic acid (primary bile acids) are biosynthesized from cholesterol in the liver. They are conjugated with glycine and taurine and secreted through the bile duct into the digestive tract. In the digestive tract, these bile acids help digestion and absorption by dispersing fat components in foods by their surface-active action. The secreted bile acid is absorbed from the ileum and goes through the portal vein to return to the liver.

However, not all bile acids are absorbed in the ileum, but there are also bile acids that are flowed downstream in the digestive tract. The bile acid remaining in the digestive tract is converted into secondary bile acids by undergoing modifications such as deconjugation, 7α-dehydration oxidation, oxidation, reduction, and epimerization by the action of enteric bacteria in the digestive tract. Components that make up secondary bile acids include deoxycholic acid, lithoholic acid, and hydroxycholic acid.
acid) and 7-Dehydrocholic acid.
The secondary bile acid moves to the lower part of the digestive tract along with the contents of the intestinal tract, is absorbed from the large intestine, and moves from the blood to the liver. The effects of secondary bile acids are not limited to the digestive tract, but extend to the liver and the body. Secondary bile acids have carcinogenicity and have been reported to promote the onset of colon cancer, liver cancer, pancreatic cancer, and bile duct cancer (see Non-Patent Documents 1 to 3). It has also been shown that the carcinogenic promoter activity of secondary bile acids is much stronger than that of primary bile acids (see Non-Patent Documents 4 and 5). Furthermore, recently, it has been shown that deoxycholic acid can be related to the development of cholelithiasis in addition to cancer (see Non-Patent Document 6).
The secondary bile acid concentration can be prevented by activating lactic acid bacteria and bifidobacteria, accumulating primary bile acids in the cells, and reducing the primary bile acid concentration in the intestinal tract. There are known a method of reducing the concentration of secondary bile acids in the intestinal tract by adsorbing bile acids by yeast (see Patent Document 1), and the like (see Patent Document 2). However, as in the present application, luminococcus is increased in the intestine by ingesting DFAIII, or luminococcus is increased by ingesting luminococcus in the intestine, or raffinose, Ingesting melibiose and fructooligosaccharides with luminococcus bacteria to activate the activity of luminococcus bacteria in the intestinal tract, lowering the pH in the intestinal tract with organic acids such as acetic acid to produce secondary bile acids There has been no known method for suppressing this.
Narisawa, T., et al., J. Natl. Cancer Inst, 53, 1093-1097, 1974 Tsuda, H., et al., Gann, 75,871-5, 1984 Makino, T., et al., J. Natl. Cancer Inst., 76, 967-75, 1986 Narisawa, T., et al., J. Natl. Cancer Inst., 53, 1093-1097, 1974 Reddy, BS., Et al., Cancer Res., 37, 3238-3242, 1977 Marcus, SN., Heaton, KW., Gut, 29, 522-533, 1988 P2001-253829A P2001-97870A

  The problem to be solved is to suppress the production of secondary bile acids in the intestinal tract.

    An object of the present invention is to increase the activity of luminococcus bacteria in the intestinal tract and reduce the pH in the intestinal tract by an organic acid such as acetic acid to be generated, thereby suppressing the production of secondary bile acids. As a method for this, ingestion of luminococcus bacteria, and in addition, difructose dianhydride 3 (DFAIII), raffinose, melibiose, fructooligosaccharides or a mixture thereof as food materials for promoting the growth of luminococcus bacteria It is characterized by ingestion. Each of these can be expected to be effective alone.

  The secondary bile acid production-inhibiting microorganisms and foods and beverages of the present invention exhibit functions in the intestinal tract when ingested like normal foods and suppress the conversion of primary bile acids to secondary bile acids. As a result, carcinogenic factors in the intestinal tract are reduced, which has the advantage of reducing the risk of carcinogenesis.

Ingestion of difructose dianhydride 3 (DFAIII) can be in any form, whether it is in powder form, dissolved in water, or ingested simultaneously with other foods. The intake of difructose dianhydride 3 is effective in the range of 0.5 g to 20 g per day for an adult, and preferably 1 g to 10 g. Even if it is taken once a day or divided into several degrees, it is effective. If difructose dianhydride 3 is ingested alone without concomitant use with luminococcus bacteria, it is possible to assimilate difructose dianhydride 3 as the original intestinal bacterium in the ingested person In the person who possessed the genus Luminococcus, the growth of the original bacterium was promoted by difructose dianhydride 3 and the conversion from primary bile acid to secondary bile acid was suppressed. To do. Furthermore, raffinose, melibiose, and fructooligosaccharide can be given as saccharides that can promote the growth of luminococcus in the intestine. It is also effective to ingest these in a mixture. The amount of these sugars used is 1 g to 20 g per day for adults, and preferably 2 g to 10 g.
For those who do not have luminococcus genus bacteria that can assimilate difructose dianhydride 3 as the original intestinal bacterium, they also consume luminococcus bacterium together with difructose dianhydride 3 Thus, the conversion from primary bile acid to secondary bile acid can be suppressed.
Furthermore, even if you do not ingest difructose dianhydride 3, by ingesting a large amount (more than 1 million) of luminococcus bacteria, the conversion from primary bile acids to secondary bile acids is suppressed can do.
Ingestion of a bacterium belonging to the genus Luminococcus requires ingestion in a state in which this bacterium is alive. If it is alive, dry cells such as freeze-drying are also possible. It can be ingested in the form of granular preparations or foods and beverages to which these are added as a luminococcus bacterium or a culture containing this bacterium. Granule-like preparations and foods can be produced by conventional methods known to be formulated and powdered. Moreover, ingestion as fermented food-drinks which fermented the genus Luminococcus as one of the starters is also possible. It can be ingested as fermented milk containing luminococcus, dairy products such as cheese and butter, beverages such as drink yogurt and lactic acid bacteria beverages.

Dietary diet supplemented with difructose dianhydride 3 (DFAIII) (3%) was given to SD rats, the timing of the increase in luminococcus bacteria and changes in the intestinal flora, short chain fatty acids in the cecal contents, The bile acid composition was examined.
Rat rearing conditions
SD male rats (Japan SLC) were introduced at 5 weeks of age and preliminarily reared for 1 week with a basic diet based on AIN-93G. Thereafter, 6 rats were divided into 2 groups so that there was no difference in the body weight of the rats, and the test breeding was conducted for 2 weeks. The control group remained the basic feed, and the difructose dianhydride 3 group gave 3% of the 8% cellulose in the basic feed replaced with difructose dianhydride 3. Rats were individually housed with metal gauges, and food and water were freely available.

As a result, there was no significant difference in the amount of food intake and body weight gain between groups after 2 weeks of breeding.
The pH in the caecum was measured with a pH meter (Horiba) after diluting the caecum contents after the test about 4 times with distilled water and homogenizing. Control group is pH
7.82 ± 0.11 and difructose dianhydride 3 group had pH 5.82 ± 0.04 (p <0.01). Feeding with 3% difructose dianhydride 3 diet for 2 weeks significantly reduced the cecal pH.
The organic acid composition of the cecum contents was examined using HPLC (Shimadzu Corporation). In the difructose dianhydride 3 intake group, it was found that the concentration of acetic acid was significantly increased, and thus the pH in the cecum was lowered (FIG. 1).
The concentration of luminococcus bacteria in the cecum was measured using real-time PCR (Prisum 7000, Applied Biosystems, USA). The following two sets of luminococcus specific primers used for the measurement were used.
Primer 932F: 5'-TCGAAGCAAC GCGAAGAAC-3 '
Primer 999R: 5'-GGGAAGGCCC CGTTACG-3 '
The following were used as Taq Man probes.
Taq Man probe: 5 '-(FAM) -CAAGTCTTGA
CATCCCTCTG ACCGGC- (TAMRA) -3 '
The reaction conditions were 2 minutes at 50 degrees Celsius, 10 minutes at 95 degrees, and 15 cycles at 95 degrees for 15 seconds and 1 minute at 60 degrees to determine the number of cells of the genus Lumicoccus.
As a result, in the difructose dianhydride 3 intake group, the number of luminococcus bacteria rapidly increased with the intake of any rat (FIG. 2). In the figure, the symbol D is attached to the group ingesting difructose dianhydride 3 and C represents the rat in the control group. The numbers are rat numbers.

On the other hand, when the change in the concentration of difructose dianhydride 3 in feces was quantified by HPLC (JASCO), in the group ingesting difructose dianhydride 3, the concentration of difructose dianhydride 3 was It continued to rise, and it was found that 40% of the intake was excreted as it is (FIG. 3). However, from day 5, the concentration began to decrease gradually, and on day 14, most of the difructose dianhydride 3 was degraded and was excreted in the feces to a few percent. There was a correlation between this behavior and the behavior of the number of luminococcus bacteria. That is, with the intake of difructose dianhydride 3, luminococcus bacteria increased, reached a plateau around the fifth day, and with that, difructose dianhydride 3 decreased in feces. This indicates that difructose dianhydride 3 is located as a carbon source almost specific to the genus Luminococcus. This can be proved also from the experimental results that the luminococcus bacteria isolated from the stool can degrade the difructose dianhydride 3 in a test tube.

The amount of bile acid was measured by measuring the lyophilized feces after 2 weeks into a small centrifuge tube of about 20 mg and adding 1N NaOH.
0.5 ml of ethanol and 50 nmol of internal standard substance (nordeoxycholic acid) were added and extracted twice at 80 degrees for 1 hour. After removing neutral sterols with hexane, bond
Adsorbed to Elut C18 (Varian, USA), eluted with ethanol, and dried under reduced pressure. After dissolving in 0.5 ml of methanol, methyl esterification and trimethylsilyl etherification were performed, and the bile acid composition was measured by GC-MS (Shimadzu Corporation). Identification was performed in a selected ion detection mode, and quantification was performed by an internal standard method.
Administration of difructose dianhydride 3 dramatically increased the proportion of primary bile acids and greatly reduced secondary bile acids (FIGS. 4 and 5). This is because the pH in the cecum was lowered and the activity of 7α-dehydrating oxidase in enteric bacteria was reduced, thereby reducing the conversion reaction from primary bile acids to secondary bile acids.
A significant decrease in the secondary bile acid ratio results in a significant reduction in the risk of developing colorectal cancer, liver cancer, pancreatic cancer, and bile duct cancer.

Administration condition of difructose dianhydride 3 feeding test in human: A 40-year-old female was administered 3 g (once) of difructose dianhydride 3 for 11 days a day. Other diet and living conditions were the same as before, and no special control was performed.
The amount of bile acid was measured in the same manner as in Example 1. Administration of difructose dianhydride 3 dramatically increased the proportion of primary bile acids and rapidly decreased secondary bile acids (FIG. 6). As in this example, the intake of only 3 g daily reduced the secondary bile acid concentration dramatically. As shown in the figure, since he has a normal diet, there is a wave in the amount of bile acids every day, but the ratio between primary and secondary has changed dramatically. It can be said that the reduction in the secondary bile acid ratio has greatly reduced the risk of developing cancer including colorectal cancer.

A luminococcus bacterium was isolated from the faeces of this experimenter. The 16S rDNA base sequence of the isolated strain was determined (Sequence Table 1), and Ruminococcus
It was confirmed that it was a difructose dianhydride 3-utilizing bacterium with 98% homology with productus, and this strain was named Ruminococcus sp. AHU1760 and deposited at the Patent Organism Depositary.
Stored as AP-20042.

Yogurt was produced using Ruminococcus sp. AHU1760 (FERM AP-20042) as a starter. The fungus was ingested into a 10% solution of skim milk and fermented at 37 degrees Celsius for 16 hours. The solution having an initial pH of 6.3 was lowered to pH 5.0 as a result of fermentation, and the liquid was yogurt-like gelled food. This fermented food was yogurt made with lactic acid bacteria and had a unique taste and a unique taste.
When 100 g of yogurt produced in this way was ingested daily for 1 week, the ratio of secondary bile acids among the bile acids contained in feces was 10
Reduced to less than%. Therefore, by ingesting fermented foods using luminococcus as a starter, the amount of secondary bile acids in the large intestine can be reduced, and the risk of colorectal cancer can be reduced.
Foods intended to increase the genus Luminococcus can be used as foods that reduce colorectal cancer risk. In addition, fermented foods obtained by adding difructose dianhydride 3 or raffinose, melibiose and fructooligosaccharides to this yogurt are also possible.

  The risk of serious diseases such as colorectal cancer can be reduced by ingesting the food / beverage product or food material of the present invention in a normal diet. Both humans and animals are effective and can be used as animal feed.

It is the figure which showed the organic acid composition of the caecum contents of a rat. (Example 1) It is the figure which showed the change of the number of micrococcus bacteria of the rat cecal contents. (Example 1) It is the figure which showed the amount of difructose dianhydride 3 excreted in the feces and the change of the number of micrococcus bacteria of the rat cecal contents. (Example 1) It is the figure which showed the bile acid composition of the cecal contents of a rat. (Example 1) It is the figure which showed the content of FIG. 4 so that a primary and secondary bile acid could be understood easily. (Example 1) It is the figure which showed the change of the bile acid composition of human feces. (Example 2)

Explanation of symbols

DFA3 Difructose dianhydride 3
CA cholic acid (primary bile acid)
CDCA chemodeoxycholic acid (primary bile acid)
α-MCA α-Muri cholic acid (primary bile acid)
β-MCA β-Muri cholic acid (primary bile acid)

7-dehydroCA 7-dehydrocholic acid (secondary bile acid)
DCA deoxycholic acid (secondary bile acid)
LCA lyso-cholic acid (secondary bile acid)
HDCA Hydroxycholic acid (secondary bile acid)

Claims (5)

A secondary bile acid inhibitor comprising a genus Ruminococcus and / or di-D-fructofuranose-1, 2 ': 2,3'-dianhydride (abbreviation DFAIII). The genus Ruminococcus belongs to the Luminococcus sp. Strain AHU1760 (FERM
The secondary bile acid inhibitor according to claim 1, which is AP-20042). Food-drinks containing the secondary bile acid inhibitor of Claim 1 or 2. Animal feed comprising the secondary bile acid inhibitor according to claim 1 or 2. Fermented food produced by using Lumicoccus spp. As a fermentation starter.