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Use of gnotobiotic mice to identify and characterize key microbes responsible for the development of the intestinal immune system.

1. Introduction

The human gastrointestinal tract harbors more than five hundred phylotypes of microbes based on 16S rRNA gene sequences, and approximately a hundred trillion individual microbes, which is more than the number of host cells. (1,2) The contribution of this great number of gut microbes to the metabolism and physiology of the whole body cannot be ignored. Furthermore, the external organs of the body are also in close association with indigenous microbes. (3) The development of methods for the cultivation of strict anaerobes in bacterial ecosystems, and the classification of these microbes, as pioneered by Mitsuoka et al., (4) have paved the way for the study of intestinal microbiota. Further advances in cultivation-independent methods for microbial analysis, including the targeting of not-yet-cultivable bacteria, have been made possible with the introduction of molecular methods based on 16S rRNA gene sequence. (5,6) Moreover, it is now possible to conduct a comprehensive analysis of the microbiota by directly reading the DNA sequence of the microbes with the use of next-generation DNA sequencing. As a result, a limited number of enterotypes are postulated to be present in each individual irrespective of geographic location or sex. (7)

Intestinal microbes profoundly affect the host physiology, and reciprocally, intestinal physiological conditions affect the composition and metabolism of the microbes, with two-way communication. It is assumed that the composition of the intestinal microbiota of healthy individuals is balanced with the host physiology, shaping symbiosis between host and microbes. In diseased conditions or under antibiotic usage, a different profile of microbiota to that found in healthy conditions is observed, which is associated with the occurrence and progression of diseases. (8) Accordingly, if it were possible to replace the microbiota of patients with that of a healthy person, a recovery from the disease might be expected. Several clinical trials of patients suffering from Clostridium difficile infection, (9,10) inflammatory bowel disease (IBD), (11,12 ) or type II diabetes (13) have been performed, and promising results have been obtained. These clinical studies strongly impact on the concept of the normal microbiota not only clinically but also microbiologically.

In animal models, many comparative studies have been performed between germ-free (GF) animals and specific pathogen--free (SPF) or conventional (CV) animals based on the concept of normal microbiota. GF rats and mice were first produced in 1945 and 1954, respectively, by Reynier and his associates of the University of Notre Dame in the United States (14) and were thereafter utilized in biomedical studies. In Japan, GF guinea pigs were produced by Miyakawa in 1954, and GF rats and mice were widely utilized in the latter half of the 1960s. (15) Although it was concerned whether the intestinal microbiota is indispensable for the survival of animals before appearance of GF animal, the life span of a GF rat is rather longer than that of a CV rat, partly due to the absence of infectious incidents. (16)

The gastrointestinal tract, in particular the epithelial cells, is the first line of defense against the external pathogens, and is greatly influenced by environmental factors, such as microbial products. Intestinal microbes affect the proliferation and differentiation of the cryptal epithelial cells by changing the production of mucus (17) or antimicrobial proteins (18) by goblet cells, the production and release of biologically active peptides by enteroendocrine cells, (19) or the epithelial cell kinetics. (20) Intestinal metabolism by microbes deconjugates the bile acids, promoting their absorption by the ileum, (21) or converts the primary bile acids into secondary ones, which are suggested to be associated with promotion of carcinogenesis. (22) Short-chain fatty acids, which are major products of intestinal microbes, contribute to the energy acquisition in the colon by the host (23) and are well known to affect the physiology of the gastrointestinal tract. (24) Liver and brain functions are also suggested to be modified by the presence of the intestinal microbiota. (25)

Currently, colonization by more than several tens of intestinal microbes isolated from indigenous microbiota is thought to be necessary to elevate the colonization resistance and IgA response in gnotobiotic mice (26,27) to the levels of CV ones because normalization of the cecal size and other physiological and histological characteristics of GF animals by association with one or a few kinds of bacterial species has not been successful. The kinds of microbes responsible for the development of mucosal immune system and how the intestinal microbes affect the host physiology remains unclear. However, the use of GF animals or gnotobiotes associated with particular microbes including not-yet-cultivable bacteria is expected to resolve these questions. Because the epithelial layer is located close to the immune cells, which react to challenges from the external environment, my colleagues and I have attempted to answer these questions by examining the biochemical differences between the intestinal epithelial cells of GF and conventionalized (Cvd) mice associated with fecal microbes derived from CV mice. This review will describe differences in the intestinal glycolipids and the intestinal immune system including IELs, IgA, and Thl7 cells between GF and CV mice and key intestinal microbes responsible for the development of these immunological activities.

2. Molecular markers for monitoring the effects of microbiota on the host

To evaluate the effects of microbiota on the development of the intestine, we first explored the molecular components of the epithelial cells of the small intestine because the genealogy and cell kinetics of these cells is well known compared with those of the large intestine. As the first step, GF mice and conventionalized (Cvd) mice (i.e., GF mice that were orally inoculated with a suspension of fecal microbiota from conventionally reared mice and then kept in a conventional animal room) were injected with radiolabeled precursors for the synthesis of the glycoprotein and glycolipid components of the epithelial cell surface. In this study, we used L-[6-[sup.3]H]-fucose, known to be incorporated into glycoconjugates almost without conversion into other sugar nucleotides, and also D-[l-[sup.14]C]-glucosamine and L[-4,5-[sup.3]H]-leucine to efficiently label the carbohydrate and protein portion of the glycoproteins, respectively. The microvillar membranes (MVMs) of the small intestinal epithelial cells were then partially purified according to the methods of Fujita. (28) Incorporation of radiolabeled compounds into the protein fraction of the MVMs was greater in Cvd mice than in GF mice after intraperitoneal injection with L-[6-[sup.3]H]-fucose or D-[l-[sup.14]C]-glucosamine, whereas L-[4,5-[sup.3]H]-leucine incorporation into this fraction was almost equal in both groups. (29) A similar difference between Cvd and GF mice was found for radiolabeled compounds incorporated into individual protein molecules in the MVM fraction, such as sucraseisomaltase complex and maltase protein, which were isolated by immunoprecipitation with a polyclonal rabbit antibody against each molecule. (29)

In contrast to [sup.14]C-glucosamine, [sup.3]H-fucose was scarcely incorporated into the lipid fraction of MVMs isolated from GF mice and extensively incorporated into the equivalent fraction from Cvd mice (30) (Fig. la). Autoradiography of the thin layer chromatography (TLC) plate on which the MVM lipid fraction of Cvd mice was separated showed a radioactive band present just beneath the band corresponding to the main glycosphingolipid of mouse intestinal epithelial cells, asialo ganglioside GM1 (GA1) (Fig. lb). These results demonstrate that the attachment of fucose moieties to lipid fraction of the MVMs of epithelial cells is drastically influenced by the association with microbiota. The chemical structure of this glycolipid was found to be [alpha](l-2) fucosyl GA1 glycosphingolipid (FGA1) (Fig. lc), of which the long chain base and fatty acids were C-18 phytosphingosine and 2-hydroxy fatty acids, respectively. (31) Interestingly the chemical structure of the ceramide of this glycosphingolipid was different from that of glycosphingolipids isolated from other origins except kidney tissue. (32) There also exists a clear difference in the sugar portion of sphingoglycolipid molecules between epithelial cells and non-epithelial tissue. (33,34)

3. Activity of a( 1-2) asialo GM1 fucosyltransferase as a sensitive marker for microbiota-induced development of the small intestine

We next investigated the age-dependency of FGA1 synthesis during the microbial association process by examining [alpha](1-2) asialo GM1 fucosyl-transferase (FT) activity35) in mice that were conventionalized at different ages by treatment with adult mouse feces. FT activity was determined by measuring incorporation of GDP-[sup.14]C-fucose in the presence of intestinal GA1 glycolipid and Triton X-100. When GF mice were conventionalized at more than four weeks of age, FT activity was abruptly induced within a week of the microbial association. By TLC analysis of glycolipids, we confirmed conversion from GA1 into FGA1, coincident with FT activity, during the course of the conventionalization. In the case of GF mice that were conventionalized a week after birth, FT was induced in an overshoot fashion during the weaning period. In CV mice raised under conventional microbial conditions, FT increased only around the weaning period, and then returned to low levels. (36) These data strongly suggest that the key microbes for FT induction expand in number around the weaning stage and are absent in the intestine before weaning.

Next, we tried to develop mice with simpler microbiota compositions than those found in CV mice. To this end, several kinds of gnotobiotic mice were prepared by treating GF mice with the following isolated strains: Escherichia coli, Proteus sp., Lactobacillus acidophilus, Lactobacillus fermentum, Lactobacillus murini, Streptococcus faecalis, Bacteroides sp., and Bifidobacterium sp. None of the monocolonized or multi-species colonized gnotobiotic mice induced substantial levels of FT activity in the small intestinal epithelial cells. (37)

Spore-forming microbes that have a characteristic morphology and adhere tightly to epithelial cells have been detected historically in the small intestine of a wide range of animals, fish, and insects. (38) These bacteria are idiomatically called "segmented filamentous bacteria (SFB)". Their successful cultivation has not been reported to date. We found that monocolonization by SFB induced FT activity in the small intestine and the development of the mucosal immune system. (39) Subsequently, monoassociation of Bacteroides thetaiotaomicron, a non-spore forming microbe of human origin, with GF mice was also reported to induce [alpha](l-2) fucosylransferase. (40)

4. FT induction and its physiology

FGA1 expression and FT activity were investigated in post-mitotic development of the intestinal epithelial cells. Cryostat sections were prepared from the small intestine in the course of conventionalization of GF mice and then stained with polyclonal rabbit antibodies against GA1 or FGA1. FGA1 was much more strongly expressed in epithelial cells from the villus portion of the small intestine than in those from the crypt portion or Peyer's patch (PP) covering follicle-associated epithelial cells, whereas GA1 was strongly expressed in the epithelial cells both from villus and crypt portions and in the follicle-associated epithelial cells in PPs (41,42) (Fig. 2), and FGA1 was maximally expressed several days after conventionalization, coincident with the TLC profile mentioned above. (35) In epithelial cell preparations isolated longitudinally along the villus-crypt axis, as expected from immunohistochemical stainings, the FT activity was stronger in the tip to mid villus portion compared with the crypt portion. (36,42)

In the two differentiation process of the small intestine (i.e., post-partum and post-mitotic differentiation along the crypt-villus axis) of CV or Cvd mice, we observed that FT activity correlated with the degree of differentiation of the epithelial cells.36)'42) However, FT activity was never observed in the small intestine in the absence of microbiota, except under the unusual conditions described below. Therefore, we consider that FT is another type of differentiation marker, different from the intestinal digestive enzyme such as sucrase-isomaltase complex expressed in the villus differentiated epithelial cells just in the weaning stage in both CV and GF mice. (36)

In colonic tissue, FGA1 was clearly expressed in CV and Cvd mice, and even in GF mice, whereas GA1 was present at much lower levels. FT activity was present to some extent in GF mice and was elevated by conventionalization (unpublished data). We conclude that FT activity in the colon is regulated in a complex manner, either dependently or independently of the microbiota. These findings suggest that some factors required for FT activity are present in GF mice, even in the absence of microbiota.

Under GF conditions, we observed FT induction around the wounded intestinal tissue resulting from a needle puncture, or in the small intestinal epithelial cells of mice intraperitoneally injected with cycloheximide or emetine (i.e., protein synthesis inhibitors). (36) Furthermore, proteinaceous substances extracted from the intestinal tissue were able to induce FT activity following intravenous injection into GF mice. (36) Due to the dependency of FGA1 synthesis on MyD88 (43) in Cvd or CV mice but not the Severe Combined Immunodeficiency (SCID) mutation (unpublished data), innate immunity rather than acquired immunity is suggested to be involved in this event. Therefore, it is possible that substances such as cytokines derived from non-T and non-B cells such as innate lymphoid cells (ILCs) are involved in FT induction. Although intravenous administration of interferon [alpha]/[beta] or interferon [gamma] into GF mice did not effectively induce FT (unpublished data), many cytokines are now considered to be candidates for the role of [alpha](l-2) fucosyltransferase inducer (Goto, Y. et al, submitted for publication). Interestingly, cycloheximide treatment and administration of the proteinaceous substances acted synergistically to induce FT, (36) as observed in "super-induction" of a protein or its mRNA in cultured cells, which is previously so called because of marked enhancement of production in the presence of cycloheximide. (44,45)

Analysis of the glycolipids in the intestinal epithelial cells of Fut2 gene knockout mice strongly indicates that either FT is the product of the Fut2 gene or its expression is under the control of this gene, consistent with the absence of Fut2 transcript in knockout mice. (46) In humans, it was recently suggested that a nonsecretor genotype (i.e., a mutation in the FUT2 gene) is closely associated with susceptibility to IBDs such as Crohn's disease (47) or viral infection. (48) Moreover, a non-secretor or low secretor genotype is reported to be associated with severe outcome in premature babies, (49) while a secretor genotype is highly associated with colonization by Bifidobacterium. (50) Intestinal bacteria that induce FUT2 expression, if present in humans, have the potential to stimulate colonization by Bifidobacterium and to play a protective role against viral infection.

5. Differences in dynamics and activity of intraepithelial lymphocytes between GF and Cvd mice

Because of the difficulties in discovering a specific microbe with a physiological impact on FT-mediated activation of intestinal mucosa, another evaluation system for the microbial effects was required. We considered that intraepithelial lymphocytes (IELs) might be suitable for this purpose because they reside within the intestinal epithelia and function as a first line of defense against infections. T cell receptor (TCR)[alpha][beta] or TCR[gamma][delta] T cells bearing CD8[alpha][alpha] directly migrate from the thymus into the interepithelial space as "natural IELs" with self-reactivity, whereas TCR[alpha][beta] T cells bearing CD8[alpha][beta] or CD4 are recruited as "induced IELs" with cytotoxic activity after activation by antigens in the lamina propria, PP, or mesenteric lymph node. (51) The recent observation that identical T cell clones are located in the lamina propria and interepithelial cell space and circulate in the thoracic duct lymph (52) supported the differentiation pathways and functions of "induced IELs".

We investigated the dynamics of the IEL population during the conventionalization of GF mice. The number of TCR[alpha][beta] IELs bearing CD8aa or CD8[alpha][beta] markedly increased to reach the maximum approximately one month after conventionalization. In contrast, the proportion of total IELs that were TCR[gamma][delta] IELs or TCR[alpha][beta] IELs bearing CD4 showed only a small increase or a decrease over the same time period. (53) This was confirmed by our subsequent observation that the increase in BrdU-labeled TCR[alpha][beta] IELs was greater than that of TCR[gamma][delta] IELs during the course of the conventionalization process and in CV mice. (54) Furthermore, cyclophosphamide abrogated the expansion of IELs two to three weeks after conventionalization, suggesting the involvement of a TCR-mediated pathway. (55) CD8[alpha][alpha]+ and CD8[alpha][beta]+ TCR[alpha][beta] IEL subsets increased equally in the course of conventionalization, whereas only CD8[alpha][beta]+ TCR[alpha][beta] T cell subset markedly increased in the mesenteric lymph node after conventionalization. Given that the increase in each subset of IELs was not abrogated by thymectomy, the microbiota probably affects the T cell development after selection in thymus or their migration into intraepithelial space. CD8[alpha][alpha]+ TCR[alpha][beta] "natural IELs" with self reactivity and CD8[alpha][beta]+ TCR[alpha][beta] "induced IELs" with cytotoxic activity are considered to bear protective functions against cancerous or injured epithelial cells and pathobiont-infected cells, respectively. (51) Accordingly, conventionalization of GF mice may provide hosts with the ability to protect themselves by expansion of IELs. (53)

We found that expression of MHC class II [I-A]molecules in the epithelial cells of the small intestine is induced a week after conventionalization, whereas the level of the non-classical MHC class I molecule, TLa, does not change during this process. (56) This MHC class II induction was mediated by TCR[gamma][delta] IELs activated by microbiota. (57) In contrast, classical MHC class I molecules such as H-2K were expressed to the same extent in both GF and Cvd mice. Although the contribution of TCR[gamma][delta] IELs and CD4+TCR[alpha][beta] IELs to the dynamics of whole IELs population is small compared with that of CD8+ TCR[alpha][beta] IELs in the course of conventionalization, TCR[gamma][delta] IELs in particular are thought to play an important role in epithelial MHC class II expression. (57)

We then fractionated the microbes in microbiota by using chloroform treatment, introduced them to GF mice, and monitored the dynamics of the IELs and checked the epithelial cell characteristics. Chloroform treatment of fecal suspensions is currently used to select spore-forming microbes from the microbial population. (58) Treatment of GF mice with chloroform-treated fecal microbiota expanded the IEL population and caused expression of MHC class II molecules and FGA1 glycolipid in the epithelial cells; (59) furthermore the IELs acquired cytolytic activity against P815 cells (derived from mouse lymphoblast-like mastocytoma).

Based on these experimental results we explored the defined microbial fraction responsible for both the increase in TCR[alpha][beta] IELs and the acquisition of redirected cytolytic activity against P815 cells. To this end, we compared gnotobiotic mice associated with several microbial preparations derived from various origins with or without chloroform treatment. Both the chloroform-treated and native forms of mouse fecal microbiota induced an increase in TCR[alpha][beta] IELs and their cytolytic activity in mouse, but similar preparations from rat or human had no effect60) (Fig. 3). Moreover, an admixture of cultivable intestinal bacteria obtained from rodents or human at that time was also ineffective. Together, these results suggest that mouse-derived microbes that form spores are sufficient for activation of IELs in the mouse small intestine. These results strongly suggest stringent host specificity of the key microbes, consistent with observations reported later by Chung et al. (61)

6. Contribution of SFB to the development of the mucosal immune system

As mentioned above, SFB are present in the small intestine of a wide range of species, but their precise functions are still unknown, largely because they have not been cultivated to date. We decided to establish SFB-monocolonized mice to assess the immunostimulatory activity of SFB. Our main strategy for preparation of the gnotobiotic mice was to use EDTA treatment to isolate the epithelial cells of the small intestinal mucosa, a part of which were tightly bound to SFB, and then to remove all other living bacteria from these epithelial cells by repeated washing and centrifugation steps. The resultant epithelial cell preparation was treated with chloroform to exclude contamination by non-spore forming microbes. The final materials containing SFB spores were orally inoculated into GF BALB/c mice as little as possible by using a stomach tube; the minimum dose necessary to produce clearly detectable bacteria in the feces was used. One to two weeks after inoculation, a large number of SFB and a small number of Bacillus sp. colonized the GF mice. Thereafter sequential dilution of the feces of the first generation of gnotobiotic mice and administration of these feces into GF mice was repeated until the appearance of apparently SFB-monocolonized mice free from Bacillus. To check the homogeneity of the bacteria that colonized the intestine for each mouse, 16S rRNA gene sequences of approximately ten clones of randomly selected recombinants were determined by using the clone library method. The 16S rRNA gene sequence of each clone was almost identical as far as we checked. For each mouse, fluorescence-isothiocyanate in situ hybridization with a probe designed based on this 16S rRNA gene sequence showed positive staining of all the bacteria found in a smear preparation of the fecal suspension. At this point, we considered that the gnotobiotic mice were SFB-monocolonized and suitable for further analysis. (39)

By conducting differential interference contrast and scanning electron microscopy (SEM) analyses of these SFB-monocolonized mice, we demonstrated that SFB colonized both the small and large intestines (39) and tightly adhered to the MVMs of the epithelial cells of the small intestine (62) (Fig. 4) and a part of the cecum, but not the colon (data not shown). In the small intestine, SFB tightly adhered to both the villus- and the PP follicle-associated epithelial cells. In Cvd and CV mice, SFB colonized the ileum at maximum density compared to other intestinal tissues. (63)

We then performed SFB-monocolonization of GF mice by oral inoculation of the fecal suspension of the gnotobiotic mice established above, and measured various activities of IELs and IgA production and evaluated the characteristics of the intestinal epithelial cells.

i) IELs. During the course of SFB monocolonization, the percentage of IEL cells in each IEL subpopulation was determined. Between two and three weeks after SFB inoculation, the percentages of TCR[alpha][beta] IELs and TCR[gamma][delta] IELs drastically increased and decreased, respectively, to reach a similar percentage to each other (39) (Fig. 5). The percentages then remained constant until the end of the observation period (Fig. 5a). The percentage of TCR[alpha][beta] IELs bearing CD8[alpha][beta] heterodimer molecules in SFB-mono-associated mice was different from that in CV (39) or Cvd mice (64) (Fig. 6a). This is extremely interesting due to differences in the differentiation route and protective functions between "natural IELs" bearing TCR[alpha][beta] and CD8[alpha][alpha] and "induced IELs" bearing TCR[alpha][beta] and CD8[alpha][beta], as described above. SFB may affect the activation process of TCR[alpha][beta] CD8[alpha][beta]+ T cells in the lamina propria, PPs, or mesenteric lymph node, and the subsequent recruitment process of IELs. Monoclonal antibody analysis of the V[beta] usage of TCR[alpha][beta] IELs and their CD8[alpha][alpha]+ and CD8[alpha][beta]+ subtypes showed almost no difference in V[beta] usage, except for V[beta]6 among SFB-monocolonized, Cvd, and GF mice. (64) During SFB-monocolonization, only V[beta]6+ TCR[alpha][beta] IELs bearing CD8[alpha][beta] notably increased among the V[beta] repertoire examined. Redirected cytolytic activity of IELs of SFB-monocolonized mice against P815 cells was observed in the presence of anti-TCR[alpha][beta] but not anti-TCR[gamma][delta] monoclonal antibody, suggesting selective activation of TCR[alpha][beta] IELs for cytolytic activity by SFB (39) (Fig. 5b).

ii) IgA and epithelial MHC class II molecules. IgA content in the feces was drastically elevated two weeks after SFB colonization (36) (Fig. 5c), consistent with the increase in IgA-secreting cells. IgA response to SFB-monocolonization in another mouse strain (Swiss) was first reported by Klaasen et a/.65) Interestingly, SFB also increased IgA-secreting cells in the colon,64) different from the IEL response described below. This finding strongly suggests that the priming for IgA synthesis occurs in PPs in the small intestine.

Immunohistochemical analysis with an admixture of antibodies against I-[A.sup.d] and I-[E.sup.d] MHC class II alloantigens indicated that induction of MHC class II molecules occurred at least three weeks after SFB monocolonization (39) (Fig. 6b).

iii) FGAl glycolipid and others. FGAl synthesis was clearly induced in the small intestinal epithelial cells within a week after SFB monocolonization (39) (Fig. 5d), similar to the finding after conventionalization. FT induction by intestinal colonization of specific bacteria, SFB, was reported for the first time. (39) The mitotic activity of the cryptal cells and differentiation of small intestinal epithelial cells, which were estimated by the metaphase-arrest method with vincristine and the ratio of the number of goblet cells to columnar epithelial cells, respectively, were also decreased by SFBmonocolonization (39) or conventionalization of GF mice. (66)

Taken together, these findings indicate that SFB-induced alterations of various characteristics of the intestinal immune system and epithelial cell surface are closely associated with physiological host responses to environmental stimuli or insults and may contribute to the maintenance of homeostasis in the digestive tract.

7. Complementary role of SFB and clostridia in the intestinal immune system

We next explored whether SFB also activate the colonic immune system. The IEL population in the large intestine, judging from the ratio of CD8+ IELs to CD4+ IELs, did not change following SFB-monocolonization of GF mice. (64) Since the usual habitat of SFB is the small intestine, not the large intestine, we tried to establish in GF mice another candidate bacteria, whose habitat is the large intestine, by orally administering an admixture of 46 clostridial strains; (64) these strains were previously reported to reduce cecal size to that of Cvd mice by their association with GF mice. (67) In contrast to the result obtained with SFB-monocolonized mice, clostridia-colonized mice showed an increase in the number of IELs and IgA-producing cells in the colon, but not the small intestine, as well as no expression of epithelial MHC class II in the small intestine. (64) IgA production in the colon was enhanced not only by clostridia but also by SFB, probably due to the priming of IgA induction in PPs of the small intestine colonized by SFB. We speculate that the effects of both types of bacteria on the mucosal functions including the immune system are complementary, with SFB affecting the small intestine and clostridia affecting the large intestine, respectively, corresponding to their primary habitats. Although the ratio of CD8[alpha][beta]+TCR[alpha][beta] to CD8[alpha][alpha]+TCR[alpha][beta] IELs was higher in SFB-monocolonized mice than in Cvd mice, addition of clostridia returned the ratio to normal (z.e., the level in Cvd mice). (64) Thus, the mice associated with both types of bacteria show activation of the mucosal immune system along the whole intestine as observed in CV or Cvd mice.

These results led us to hypothesize that not all members of the microbiota are necessary for activation of the intestinal mucosal immune system including the epithelial functions, and that limited kinds of bacteria such as SFB and clostridia are sufficient to develop the immune system. The presence of other indigenous intestinal bacteria such as Bacteroides acidifaciens (68) in addition to this bacterial combination is speculated to alter or modify the intestinal immune system beneficially or harmfully for the host. We called this minimum bacterial combination of SFB and clostridia "basal flora" or "minimal flora". (60) In the case of IBD models such as SAMPl/Yit mutant mice on the AKR background with spontaneous ileitis, (69) and mice with dextran sodium sulfate-induced colitis, neither ileitis nor colitis developed in ex-GF mice that were not only associated with basal flora but also mono-associated with IBD-derived Bacteroides vulgatus. (70) However, IBD-like diseases clearly occurred following addition of Bacteroides vulgatus to basal flora-associated mice (unpublished data). A similar observation was recently reported by Stephankova et al., (71) where particular microbiota members except SFB seemed to alter the immune system being developed by SFB to induce or exacerbate intestinal inflammatory responses. In this case it is very difficult to evaluate the boundary, if present, between commensal bacteria and pathogenic ones. (72)

SFB and clostridia not only play a complementary role in the development of the mucosal immune system of the digestive tract, as described above, but they also contribute to the development of Thl7 cells (T helper cells that produce interleukin 17) in the small intestine (73,74) and Treg cells (regulatory T cells) in the colon. (75,76)

8. Role of SFB as a Thl7 inducer

The discovery of Treg cells and Thl7 cells, and their close association with gut functions in health and disease, (77-79) is big topic in the field of immunology. A large populations of Treg or Thl7 cells are present in the intestinal mucosa and these cells are suggested to be involved in the occurrence and repression of infectious diseases or IBD. (62,80)

Notably, Ivanov et al. observed a close relationship between the density of Thl7 cells in the lamina propria of the small intestine and the presence of particular bacteria. They found that a mouse strain C57BL/6 raised at Taconic Farms, has many more Thl7 cells than the same strain raised at the Jackson Laboratory. (81) This observation indicates that a limited number of characteristic bacteria, such as SFB or Lactobacillus murinus, that are present in the mice from Taconic Farms, but not the Jackson Laboratory, play a key role in Thl7 cell development. Addition of SFB to Jackson Laboratory mice, which were SFB-free according to the results of a PhyloChip (82) assay, clearly evoked an induction of Thl7 cells (73) (Fig. 7a). Furthermore, induction of Thl7 cells has been confirmed in SFB-monocolonized mice but not in the mice colonized with 46 strains of clostridia (73) (Fig. 7b) that were used for the study of IELs and IgA described above. Interestingly, transcripts of all isoforms of the serum amyloid A (SAA), Saal, Saa2, and Saa3, were enormously upregulated in the epithelial cells of SFB-monocolonized mice and in Jackson Laboratory mice cohoused with Taconic Farms mice, according to the results of microarray analysis. (73) Addition of SAA to in vitro cultivation of the naive T cells with lamina propria dendritic cells (DCs) in the presence of anti-CD3 produced Thl7 cell cytokines such as IL-17A, IL-17F, and ROR[gamma]t. This result suggests a possibility that naive CD4+ T cell differentiates to Thl7 cell via IL-23 produced by SAA-stimulated DCs. (73) More recently, analysis of Thl7 cell differentiation mechanism by SFB remarkably advanced. Most Thl7 cells in lamina propria of SFB-monocolonized mice recognize particular SFB peptides (83) and also this SFB antigen is presented by DCs through their MHC class II expression. (84)

Physiologically, Citrobacter rodentium infection was repressed to keep the normal cryptal depth in SFB-colonized Jackson Laboratory mice compared with SFB-free Jackson Laboratory mice. (73) Before the appearance of the Thl7 cell concept, SFB colonization was reported to be negatively correlated with pathogenic E. coli 0103 colonization in rabbits (85) suggesting that it inhibits infection. More interestingly, the SFB population expands abnormally in the small intestine of mice with disruption of the activation-induced cytidine deaminase (AID) gene, (86) which also greatly contributes to IgA production in the intestine. (87) Thus IgA secretion is thought to play an important role in leaving intestinal microbes in their appropriate niches.

Involvement of the microbiota in autoimmunity became of great concern after this discovery of Thl7 cell-inducing commensal microbe. Induction of disease by SFB-monocolonization of GF mice was attempted in several mouse models of autoimmune disease as described below. When arthritis model GF K/BxN mice, which express a TCR transgene that recognizes a self-peptide derived from glucose-6-phosphate isomerase, were inoculated with SFB, the disease score greatly increased, coincident with the appearance of Thl7 cells in the lamina propria in the small intestine. (88) In a mouse model of experimental autoimmune encephalomyelitis, GF mice (C57/BL6) were inoculated with an SFB isolated by us (39) together with myelin oligodendrocyte glycoprotein (MOG) peptide and purtussis toxin. Disease development was observed, although it was weaker than that in SPF mice. (89) In this case the Thl7 cells expanded in the spinal cord rather than in the intestinal lamina propria. Furthermore, SFB affected the disease development in the type 1 diabetic model mouse following SFB-inoculation (90) or following natural transmission of SFB. (91) Among these autoimmune models, the characteristics of the Thl7 cells, such as their anatomical site and [gamma]-interferon production ability seem to be different. The interrelationship between autoimmune diseases and SFB is currently being clarified.

9. Host-specificity of SFB in epithelial binding and mucosal immune stimulation

As mentioned above, SFB are present in a wide range of animals. (38) Because of their uncultivability, the only reported host-specific differences between SFBs relate to their colonization ability (92) and 16S rRNA gene sequences. (93,94) We have isolated SFB not only from BALB/c mouse (mSFB)39) but also from F344 rat (rSFB). (94) Our observations in mSFB or rSFB and mouse- or rat-microbiota colonized mice, and the findings of Chung et al., (61) suggest that a strong relationship exists between the adhesion ability of SFB and their effects on the host mucosal immune system.

When mSFB and rSFB were inoculated into GF mice, both SFBs colonized almost equally both the small and large intestines. However, tight adhesion of rSFB to the mouse small intestinal epithelial cells was not detected by SEM and real-time PCR. Furthermore in ex-GF mice that were monocolonized with rSFB, IELs were not expanded, IgA scarcely increased at all, MHC class II molecules were not expressed, and Thl7 cell induction in the lamina propria was not observed. As described above, the opposite was the case for mSFB-monocolonized mice. Thl7 cell induction in the lamina propria was observed in mSFB-monocolonized but not rSFB-monocolonized mice. Concomitantly, when mSFB or rSFB were inoculated into GF rats (F344), only rSFB adhered tightly to the rat small intestinal epithelial cells, coincident with Thl7 induction, IEL response, and IgA secretion (in preparation for submission). These findings indicate that SFB exhibit clear host-specificity between mice and rats, particularly in the small intestine. We therefore consider it likely that SFB affect the host mucosal immune system in a host-specific manner in a wide range of the animals, and that the host-specific effect of SFB contributes to the host-specific effect of the whole microbiota on the host mucosal immune system, such as the changes in Treg cells, Thl7 cells, and IgA-producing cells observed in Cvd mice by Chung et al. (61) In comparison with Cvd mice, the degree of the activation among various parts of the immune system in SFB-monocolonized mice is variable; for example, the number of Thl7 cells is almost equal between Cvd and SFB-monocolonized mice, whereas that of IELs is much greater in Cvd mice than in SFB-monocolonized mice. In contrast, IgA content is somewhat higher in SFB-monocolonized mice than in Cvd mice, probably due to degradation by microbial IgA-protease present in Cvd mice (95) but not SFB-monocolonized mice.

Importantly, host-specificity of SFB for activation of the mucosal immune system is likely to be dependent on the tight adhesion to the small intestinal epithelial cells, where polymerization of actin filaments occurs, (96) as observed in signal transduction by epithelial adhesion of enteropathogenic E. coll. (97) Clarification of the precise mechanisms of tight adhesion is required to elucidate how SFB activates the mucosal immune system.

10. Genomic view of differences between mSFB and rSFB

As described above, mSFB and rSFB have stringent host-specificity regarding adhesion to epithelial cells and immune stimulation. We consider that whole genome analysis might suggest a mechanism for these host-specific effects. The genome sizes of mSFB and rSFB are 1.59 Mb and 1.52 Mb, respectively (63) (Table 1), which is approximately half that of clostridial genomes, and nucleotide identity between the mSFB and rSFB genomes is 86%. The larger size of the mSFB genome compared with the rSFB genome corresponds to the integration of two prophages specifically into the mSFB genome. The genome sizes of both SFBs are intermediate between those of free-living bacteria and host-dependent symbionts, suggesting that SFB may have both characters. (98) Both SFB genomes encode flagellin proteins, although there is no reported SEM image of the flagellar filaments. Although the amino acid sequence of the flagellin protein FliC, which is assumed to be responsible for its binding to mouse TLR5, (99,100) is almost identical between the two SFBs, rSFB was not effective for immunostimulation of mice. Furthermore, although ADP-ribosyltransferase, which may be involved in modulation of host responses, is encoded by the prophages that are integrated in the mSFB genome only, as suggested by Pamp et al., (101) rSFB was effective for immunostimulation in rats. Therefore, no promising functional gene candidate for the regulation of SFB-induced immunostimulation has yet been found, and further investigation is required. The genomic sequence of mSFB preparation isolated and determined by another group (102) and that of our mSFB preparation determined by another group (103) are almost identical to the sequence published by ours. (63) Moreover, the DNA sequences of individual SFB microbes isolated from our SFB preparation by using a single-cell manipulator technique (101) suggest that the mSFB preparation originally isolated from mice in our laboratory (39) may be a mixture of SFB with slightly heterogeneous genome sequences.

11. Concluding remarks

While exploring the impacts of microbiota on the intestinal immune system, including epithelial cell surface changes, we discovered that enhancement of IEL recruitment and Thl7 cell induction in lamina propria, and cell surface glycolipid fucosylation in the small intestine were mediated by a type of not-yet-cultivable intestinal bacteria, that is, SFB. Although the physiological roles of IELs and FGA1 glycolipid are still obscure, we consider that the mechanisms underlying these events, including Thl7 induction, are likely to contain common elements because these events seem to be induced by tight adhesion of SFB to the inestinal epithelial cells.

Based on our analysis of TCR and CD8 molecules, the effect of SFB on IELs seems to differ from that of the whole intestinal microbiota in that it is limited to recruitment of a part of the IEL population that responds to the peripheral antigens, probably SFB cell components. The effects of SFB on immunological events are host-specific in that rSFB could not induce the events in mouse, and vice versa. Although the whole genome sequences of both rSFB and mSFB have been determined, the candidate genes responsible for the host-specificity have not been deduced as yet. However, it is clear that the rSFB and mSFB tightly adhere to both villus and PP-covered epithelial cells in the small intestine in a host-specific fashion (preparation for submission), suggesting that this is a starting point for the mechanism underlying the immunological events. Taken together, our results suggest that the tight adhesion of SFB to epithelial cells induces Thl7 cells and simultaneously activates CD8[alpha][beta]+ TCR[alpha][beta] T cells in the lamina propria following recruitment in the interepithelial space. We consider it likely that increased IgA secretion is due to the enhancement of priming by SFB-adhesion in PP-covered epithelial cells.

On the other hand, our observations of FT induction in SCID mice, but not MyD88 knockout mice, the involvement of a proteinaceous substance present in the small intestinal homogenate, and the selective expression of FGA1 in villus epithelial cells suggest that proteinaceous substances produced by non-T and non-B cells may mediate FT induction in villus epithelial cells. Our proposed activation scheme for the intestinal immune system, including cell surface glycosylation by SFB, is described in Fig. 8.

Finally, the issue of presence or absence of SFB or SFB equivalent microbes in human attracts much attention. The SFB population expands in the weaning stage, at least, in mice. (104) Although we tried in vain to find SFB 16S rRNA gene sequence in the intestinal contents of humanized ex-germ free mice associated with microbiota of human baby feces (data not shown), there are some reports suggesting the presence of SFB in humans, according to light micrography and partial 16S rRNA gene sequences. (38,105,106) Moreover, due to the presence of SFB or the morphologically similar microbes in a wide range of mammals such as rhesus monkey, (38) crab-eating monkey, (38,94) pig, (107,108) dog, (38,109,110) cat, (38) cow, (111) calf, (112) horse, (113) and rabbit, (85) there is no reason to exclude human from this group at present. Although the functions of SFB are unknown at all except rodents, SFB or SFB equivalent microbes may start to colonize or transiently colonize the human small intestine around the weaning period according to the observations in the animals mentioned above. The discovery of SFB in humans and clarification of its role in human-microbiota interplay are waiting to be done in the near future.

Caption: Fig. 1. Microbiota induces fucosylation of epithelial glycosphingolipid. (30,31) (a) Time-course of L-[6-3H]-fucose or D-[1-14C]-glucosamine incorporation into the microvillus membrane lipid fractions of small intestinal epithelial cells in GF ([??]) and Cvd mice ([??]). (b) TLC analysis (lanes 3, 4) and autoradiography (lanes 1, 2) of the lipid fraction of both groups. St represents the glycolipid standards, ceramide monohexoside (CMH), ceramide dihexoside (CDH), Globoside (Glob), Forssman glycolipid (Forss) and asialo GM1. The open arrowheads and the open circles show the bands of the glycolipids. (c) The chemical structure of the glycolipid labeled with 3H-fucose. Panels a, b are reproduced with permission from ref. 30.

Caption: Fig. 2. FGA1 glycolipid expression in the villus portion of the villus-crypt axis (42) but not in PP-covered epithelial cells. (a) The thin sections of the small intestine of Cvd mice on day 0 or day 4 after microbial inoculation were immunostained with rabbit anti-GA1 and anti-FGA1 antibodies followed by FITC-conjugated secondary antibody. (b) Thin sections of the PPs of Cvd mice at day 4 were immunostained with anti-GA1 or anti-FGA1 glycolipid antibody followed by peroxidase-labeled secondary antibody. Antibody binding was visualized by using the chromogen AEC (3-amino-9-ethylcarbazole). Panel a is reproduced with permission from ref. 42.

Caption: Fig. 3. Effect of species and chloroform-treatment of microbe preparations on induction of TCR[alpha][beta] IEL recruitment and cytolytic activity (n F 2-4). The ratio of TCR[alpha][beta] IELs to TCR[gamma][delta] IELs (gray bars) and P815-cell specific lysis (%) in the presence of anti-TCR[alpha][beta] antibody (black bars) were determined in GF mice two weeks after inoculation with microbe preparations derived from mouse, rat, or human, with or without chloroform (Chl) treatment, or an admixture of colonies grown on EG agar plate derived from mouse feces (Cultivable). GF or CV mouse feces were used as the control. All values are represented as percentage of each value of CV mice. ND: not determined. The panel is reproduced with permission from ref. 60.

Caption: Fig. 4. Tight adhesion of SFB to the small intestinal epithelial cells in SFB-monocolonized mice. Images were obtained from differential interference contrast microscopy (a, arrows) and SEM (b-d).

Caption: Fig. 5. IEL recruitment, IgA production, and epithelial fucosylation during the course of SFB monocolonization of GF mice. (39) (a) Percentage of TCR[alpha][beta] and TCR[gamma][delta] IELs to total IELs. (b) Cytolytic activity against P815 cells in the presence of anti-TCR[alpha][beta] or anti-TCR[gamma][delta] antibody. (c) IgA concentration in the cecal contents. (d) TLC profile of the change from GA1 to FGA1 glycolipid. Panels a, b, and d are reproduced with permission from ref. 39.

Caption: Fig. 6. Differences in CD8 molecules of TCR,O IELs and MHC class II expression among GF, SFB-monocolonized, and Cvd mice. (a) Flow cytometry of TCR[alpha][beta] IELs with CD8[alpha][beta] or CD8[alpha][alpha]. (b) Immunohistochemistry of small intestinal tissue with anti-MHC I-[A.sup.d] and MHC I-[E.sup.d] antibodies. Both analyses are performed using the second generations of SFB-monocolonized and Cvd mice together with age matched GF mice. Panels a, b are reproduced with permission from ref. 64.

Caption: Fig. 7. Induction of Th17 cells by SFB colonization of IQI GF mice. (a) Flow cytometry of Th17 cells in the small intestine of SFB- or Jackson Laboratory microbiota (Jax)-associated mice or the Jax mice which were additionally associated with SFB. (b) Proportion of Th17 cells (%) among CD4D cells in the small intestine of gnotobiotic mice that were associated with SFB alone or an admixture of Bacteroides or Clostridium species. Panels a, b are reproduced with permission from ref. 73.

Caption: Fig. 8. Schematic illustration of activation of the intestinal immune system including fucosylation of epithelial glycolipid by SFB. Details and non-standard abbreviations are shown in the main text.


(Received July 11, 2014; accepted Sep. 2, 2014)

(Communicated by Tasuku HONJO, M.J.A.)


I would like to first thank Dr. T. Honjo (Grad. Sch. Med., Kyoto Univ.) for encouraging me to write this review. Moreover, I deeply appreciate the work of my collaborators: Drs. T. Yamakawa and A. Suzuki (Fac. Med., Univ. Tokyo) for glycolipid research; Dr. K. Itoh (Grad. Sch. Agri. Life Sci., Univ. Tokyo) for clostridial gnotobiote research; Drs. K. Honda, K. Atarashi (RIKEN Inst.), Dr. K. Takeda (Grad. Sch. Med., Osaka Univ.), Drs. D. Littman and I. Ivanov (New York Univ. Sch. Med.) for immunological research; and Dr. M. Hattori (Grad. Sch. Front. Sci., Univ. Tokyo), Dr. T. Prakash (RIKEN Inst.), Dr. H. Morita and T. Nagamori (Azabu Univ.) for genome research. I also greatly thank the members of my team, Drs. S. Matsumoto, A. Imaoka, Y. Okada, H. Setoyama, R. Shima, S. Hara and M. Ando, with whom all of the work presented here was performed, and the animal care staff of our institute for production and maintenance of all experimental animals. Finally I sincerely thank the directors of our institute for their steady support and encouragement and all members of our institute for cooperation in this research.


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Yoshinori UMESAKI *1,([dagger])


Yoshinori Umesaki was born in Fukui Prefecture, Japan in 1950. He graduated from Department of Fermentation Technology, Faculty of Engineering, Osaka University in 1972 and completed a master's degree of the same department in 1974. He started his research carrier in Yakult Central Institute for Microbiological Research, Tokyo in 1974.

After a program of research student at the Department of Biochemistry, Faculty of Medicine, University of Tokyo (Professor Tamio Yamakawa) in 1980, he received Pli.D. from Department of Food Chemistry, Tohoku University (Professor Shuichi Kimura) in 1987, for his thesis "Analysis for Interactions between Intestinal Microbiota and Host".

Thereafter, he experienced visiting researcher of RIKEN Frontier Research Program for Intestinal Flora directed by Professor Tomotari Mitsuoka. 1987--1990 and Head of Basic Research Department II, 2006--2010 and Executive Manager, 2008--2010 in Yakult Central Institute. He is now in position of Senior Research Fellow of Yakult Central Institute and Visiting Professor of Azabu University. Throughout his carrier, he focused on the research for biological and medical significance of the interactions between the intestinal microbes including probiotics and host. A pioneering work of his research group using gnotobiotic mouse model largely contributed to the elucidation of the role of segmented filamentous bacteria (SFB) in the host-microbiota interplay.

*1 Yakult Central Institute, Kunitachi-shi, Tokyo 186-8650, Japan.

([dagger]) Correspondence should be addressed: Y. Umesaki, Yakult Central Institute, Izumi 5-11, Kunitachi-shi, Tokyo 186-8650, Japan (e-mail:

Table 1. General features of the whole genome and possible functional
gene candidates of mSFB and rSFB *

       Genome      G+C                        Number of
       size        content   CDSs   rRNA      tRNA    CRI-   Propha-
       (bp)        (%)              operons   genes   SPRS   ges

mSFB   1,586,397   28        1420   5         38      3      2
rSFB   1,515,556   28        1346   5         39      1      0


mSFB   FliC1 to FliC3
rSFB   FliC1 to FliC4

* Modified from ref. 63.
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