The notion that ingestion of so-called ‘good’ bacteria (‘probiotics’) or food components favouring growth of probiotic bacteria (‘prebiotics’) can have advantageous effects on human health arouses strong opinions, both in agreement and against. Remarkably few data have been fuelling this debate. Nevertheless, two important studies have now appeared, one published in The Lancet showing that probiotic supplementation in patients with acute pancreatitis is deleterious(Reference Besselink, van Santvoort and Buskens1) and one in this issue of the British Journal of Nutrition by Arribas et al. (Reference Arribas, Elena Rodríguez-Cabezas, Comalada, Bailón, Camuesco, Olivares, Xaus, Zarzuelo and Gálvez2), showing the beneficial effects of Lactobacillus fermentum in an experimental model of septic shock. Together with existing studies on the immunological effects of pre- and probiotic food supplementation, the main effects of such treatment seems localised to inducing anergy in the T cell compartment. Health claims of pre- and probiotic treatment should be interpreted within this framework.
The mucosal surface of the intestine represents the major contact of the body with microbiological stimuli and in this compartment is most of the immunological activity of the body. Despite the bewildering number of bacteria in the intestine, especially the colon, in most cases the human immune system acts to tolerate harmless bacteria while eliminating pathogenic bacteria. A variety of immunological mechanisms, which include the existence of an efficient colonic columnic epithelial barrier, the production of antibacterial peptides (for example, the production of α-defensins by the Paneth cells), constant sentinel-like surveillance by CD16low monocytes and efficient recruitment of granulocytes to areas in which barrier integrity has been compromised mediates protection of the body against the microbiological onslaught on the mucosal surface(Reference Braat, Peppelenbosch and Hommes3). Counterintuitively, reduced activity of these innate mechanisms, as a consequence of genetic defects, seems responsible for chronic intestinal inflammation in Crohn's disease, which is associated with an abnormally exaggerated mucosal immune response to an otherwise normal intestinal flora(Reference Comalada and Peppelenbosch4). The sheer size of the mucosal immune system as compared with other parts of the immune system makes the notion that influencing the mucosal immune system by dietary means plausible.
It usually assumed that the flora along the intestinal tract is established early in life and in mammalian organisms resembles the flora of the mother and is stable. Nevertheless, pre- or probiotic treatment seems capable of at least temporally altering this composition. Probiotics are a group of bacteria of which the Lactobacilli and Bifidobacteria are the most prominent members and it is claimed that they have anti-inflammatory properties. Accordingly, such probiotic bacterial strains protect against experimental colitis in rodents(Reference Peran, Camuesco, Comalada, Bailon, Henriksson, Xaus, Zarzuelo and Galvez5–Reference Schultz, Veltkamp, Dieleman, Grenther, Wyrick, Tonkonogy and Sartor7) as well as exacerbations of inflammatory bowel disease(Reference Gionchetti, Rizzello, Venturi, Brigidi, Matteuzzi, Bazzocchi, Poggioli, Miglioli and Campieri8) and topical allergy(Reference Kalliomaki, Salminen, Poussa, Arvilommi and Isolauri9, Reference Kalliomaki, Salminen, Arvilommi, Kero, Koskinen and Isolauri10) in human patients. In agreement, food supplements specifically enhancing the growth of probiotic bacteria are recognised to be beneficial in a variety of inflammatory conditions including inflammatory bowel disease(Reference Camuesco, Peran, Comalada, Nieto, Di Stasi, Rodriguez-Cabezas, Concha, Zarzuelo and Galvez11, Reference Ritsema and Smeekens12) and genetically engineering plants for the production of prebiotics has become an industry in its own right(Reference Ritsema and Smeekens13, Reference Weyens, Ritsema and Van Dun14) despite limited insight into the immunological mechanisms induced by such food supplementation. In contrast to most micro-organisms, some probiotic bacteria are capable of impairing the immunological reaction to their mucosal presence in particular and have a dampening effect on the adaptive immune system in general. To a certain extent probiotics exert their action by niche occupation and thus preventing colonisation of the bowel by pathogenic bacterial species(Reference Bernet, Brassart, Neeser and Servin15–Reference Tuomola, Ouwehand and Salminen17). Moreover, it has become clear that probiotic bacteria directly influence host physiology, especially barrier function(Reference Ouwehand, Salminen and Isolauri18, Reference Madsen, Cornish, Soper, McKaigney, Jijon, Yachimec, Doyle, Jewell and De Simone19), but their anti-inflammatory effects in inflammatory bowel disease(Reference Shanahan20) and topical allergic disease(Reference Shanahan20, Reference Pochard, Gosset, Grangette, Andre, Tonnel, Pestel and Mercenier21) suggest that a direct effect on the immune system is involved as well. As inflammatory bowel disease displays mainly Th1 characteristics and topical allergies are characterised by a Th2 phenotype and both benefit from probiotic supplementation, the immunological effects of probiotic bacteria probably do not involve altered Th1/Th2 polarisation. There is evidence from a double-blind placebo-controlled study that Lactobacillus reuteri protectis reduces short-term sick-leave from work caused by respiratory or gastrointestinal infections(Reference Tubelius, Stan and Zachrisson22–Reference Lara-Villoslada, de Haro, Camuesco, Comalada, Velasco, Zarzuelo, Xaus and Galvez24). This effect is also not easily explained via an influence on altered Th1/Th2 polarisation but suggests effects of probiotic treatment at a more fundamental level of human immunobiology.
The study of Arribas et al. (Reference Arribas, Elena Rodríguez-Cabezas, Comalada, Bailón, Camuesco, Olivares, Xaus, Zarzuelo and Gálvez2), which documents a preventive effect of Lactobacillus fermentum in a murine model of septic shock, provides important clues as to what these mechanisms might be. The authors document markedly reduced splenic T cell responses, suggesting that the T cell compartment might be the relevant target for many of the effects observed by probiotics. Also, the earlier observation reported by the same laboratory that different probiotic bacteria, as well as prebiotics, are beneficial in a trinitrobenzenesulfonic acid model of rat colitis (which represents a classical T cell-mediated inflammation) points in this direction. Interestingly, both in vitro as well as in human volunteers or patients with Crohn's disease, Lactobacillus rhamnosus induced an anergy-like T cell hyporesponsiveness which was apparently mediated via reduced co-stimulatory activity in dendritic cells(Reference Braat, van den Brande, van Tol, Hommes, Peppelenbosch and van Deventer25), which fits well with a scheme that pre- and probiotics act through diminished T cell activation(Reference Braat, van den Brande, van Tol, Hommes, Peppelenbosch and van Deventer25). This hypothesis also proves exceedingly useful in explaining the clinical efficacy in Crohn's disease of Lactococcus lactis expressing IL-10 where intravenous application of this IL is clinically not useful(Reference Braat, Rottiers, Hommes, Huyghebaert, Remaut, Remon, van Deventer, Neirynck, Peppelenbosch and Steidler26, Reference Fukatsu, Sakamoto, Hara, Ueno, Maeshima, Matsumoto, Mochizuki and Hiraide27); the bacterial context of the IL-10 might result in combined T cell anergy and IL-10-dependent induction of tolerance and thus be synergistic. In this context it should prove highly interesting to compare the efficacy of Lactococcus lactis expressing IL-10 to the mother organism not expressing IL-10 in Crohn's disease, but such a study has not been performed.
The molecular basis of the immunological modulation by pre- and probiotics on T cell reactivity remains unaddressed, but may lie in the secretion of soluble factors interfering with dendritic cell specific intercellular adhesion molecule 3-grabbing nonintegrin (DC-SIGN)(Reference Martin, O'Sullivan, Low and Thomas28). This may provide the bacterium with an evasive strategy with respect to the immune system and hence a competitive advantage at the mucosal surface and thus provide the bacterium with a niche for cell growth in the bowel. How bacteria prevent other micro-organisms from profiting from this niche is unclear, but evidence exists, for instance, that Lactobacillus rhamnosus is able to suppress the growth of a diverse range of other bacteria via a variety of strategies(Reference Boris, Jimenez-Diaz, Caso and Barbes29–Reference Rogelj, Bogovic Matijasic, Canzek Majhenic and Stojkovic31).
Strikingly, in the recent trial of probiotics in human acute pancreatitis(Reference Besselink, van Santvoort and Buskens1) the supermortality in the probiotic-treated group seemed mainly due to enhanced bowel ischaemia in these patients. Since there is good evidence linking bowel ischaemia severity to reduced T cell reactivity(Reference Fukatsu, Sakamoto, Hara, Ueno, Maeshima, Matsumoto, Mochizuki and Hiraide27), effects of probiotic bacteria on T cell reactivity may be linked to negative effects of probiotics in this disease.
In conclusion, also based on the study by Arribas et al. (Reference Arribas, Elena Rodríguez-Cabezas, Comalada, Bailón, Camuesco, Olivares, Xaus, Zarzuelo and Gálvez2), a picture emerges in which pre- and probiotics exert a class effect on reactivity in the T cell compartment, possibly mediated via reduced co-stimulatory activity of dendritic cells. In view of this class effect, the current emphasis in the field that each different pre- and probiotic should be considered individually and that results obtained with different strains should not be extrapolated to related strains may be somewhat overemphasised. In other words, the bioanalytical profiling of both host microbiota and probiotic will be crucial for defining how best to apply prebiotics and probiotics: optimal dosage, frequency, duration, and consequently providing a rational basis for supporting the belief that their consumption results in health benefits.
The authors have no conflict of interest to declare.
The notion that ingestion of so-called ‘good’ bacteria (‘probiotics’) or food components favouring growth of probiotic bacteria (‘prebiotics’) can have advantageous effects on human health arouses strong opinions, both in agreement and against. Remarkably few data have been fuelling this debate. Nevertheless, two important studies have now appeared, one published in The Lancet showing that probiotic supplementation in patients with acute pancreatitis is deleterious(Reference Besselink, van Santvoort and Buskens1) and one in this issue of the British Journal of Nutrition by Arribas et al. (Reference Arribas, Elena Rodríguez-Cabezas, Comalada, Bailón, Camuesco, Olivares, Xaus, Zarzuelo and Gálvez2), showing the beneficial effects of Lactobacillus fermentum in an experimental model of septic shock. Together with existing studies on the immunological effects of pre- and probiotic food supplementation, the main effects of such treatment seems localised to inducing anergy in the T cell compartment. Health claims of pre- and probiotic treatment should be interpreted within this framework.
The mucosal surface of the intestine represents the major contact of the body with microbiological stimuli and in this compartment is most of the immunological activity of the body. Despite the bewildering number of bacteria in the intestine, especially the colon, in most cases the human immune system acts to tolerate harmless bacteria while eliminating pathogenic bacteria. A variety of immunological mechanisms, which include the existence of an efficient colonic columnic epithelial barrier, the production of antibacterial peptides (for example, the production of α-defensins by the Paneth cells), constant sentinel-like surveillance by CD16low monocytes and efficient recruitment of granulocytes to areas in which barrier integrity has been compromised mediates protection of the body against the microbiological onslaught on the mucosal surface(Reference Braat, Peppelenbosch and Hommes3). Counterintuitively, reduced activity of these innate mechanisms, as a consequence of genetic defects, seems responsible for chronic intestinal inflammation in Crohn's disease, which is associated with an abnormally exaggerated mucosal immune response to an otherwise normal intestinal flora(Reference Comalada and Peppelenbosch4). The sheer size of the mucosal immune system as compared with other parts of the immune system makes the notion that influencing the mucosal immune system by dietary means plausible.
It usually assumed that the flora along the intestinal tract is established early in life and in mammalian organisms resembles the flora of the mother and is stable. Nevertheless, pre- or probiotic treatment seems capable of at least temporally altering this composition. Probiotics are a group of bacteria of which the Lactobacilli and Bifidobacteria are the most prominent members and it is claimed that they have anti-inflammatory properties. Accordingly, such probiotic bacterial strains protect against experimental colitis in rodents(Reference Peran, Camuesco, Comalada, Bailon, Henriksson, Xaus, Zarzuelo and Galvez5–Reference Schultz, Veltkamp, Dieleman, Grenther, Wyrick, Tonkonogy and Sartor7) as well as exacerbations of inflammatory bowel disease(Reference Gionchetti, Rizzello, Venturi, Brigidi, Matteuzzi, Bazzocchi, Poggioli, Miglioli and Campieri8) and topical allergy(Reference Kalliomaki, Salminen, Poussa, Arvilommi and Isolauri9, Reference Kalliomaki, Salminen, Arvilommi, Kero, Koskinen and Isolauri10) in human patients. In agreement, food supplements specifically enhancing the growth of probiotic bacteria are recognised to be beneficial in a variety of inflammatory conditions including inflammatory bowel disease(Reference Camuesco, Peran, Comalada, Nieto, Di Stasi, Rodriguez-Cabezas, Concha, Zarzuelo and Galvez11, Reference Ritsema and Smeekens12) and genetically engineering plants for the production of prebiotics has become an industry in its own right(Reference Ritsema and Smeekens13, Reference Weyens, Ritsema and Van Dun14) despite limited insight into the immunological mechanisms induced by such food supplementation. In contrast to most micro-organisms, some probiotic bacteria are capable of impairing the immunological reaction to their mucosal presence in particular and have a dampening effect on the adaptive immune system in general. To a certain extent probiotics exert their action by niche occupation and thus preventing colonisation of the bowel by pathogenic bacterial species(Reference Bernet, Brassart, Neeser and Servin15–Reference Tuomola, Ouwehand and Salminen17). Moreover, it has become clear that probiotic bacteria directly influence host physiology, especially barrier function(Reference Ouwehand, Salminen and Isolauri18, Reference Madsen, Cornish, Soper, McKaigney, Jijon, Yachimec, Doyle, Jewell and De Simone19), but their anti-inflammatory effects in inflammatory bowel disease(Reference Shanahan20) and topical allergic disease(Reference Shanahan20, Reference Pochard, Gosset, Grangette, Andre, Tonnel, Pestel and Mercenier21) suggest that a direct effect on the immune system is involved as well. As inflammatory bowel disease displays mainly Th1 characteristics and topical allergies are characterised by a Th2 phenotype and both benefit from probiotic supplementation, the immunological effects of probiotic bacteria probably do not involve altered Th1/Th2 polarisation. There is evidence from a double-blind placebo-controlled study that Lactobacillus reuteri protectis reduces short-term sick-leave from work caused by respiratory or gastrointestinal infections(Reference Tubelius, Stan and Zachrisson22–Reference Lara-Villoslada, de Haro, Camuesco, Comalada, Velasco, Zarzuelo, Xaus and Galvez24). This effect is also not easily explained via an influence on altered Th1/Th2 polarisation but suggests effects of probiotic treatment at a more fundamental level of human immunobiology.
The study of Arribas et al. (Reference Arribas, Elena Rodríguez-Cabezas, Comalada, Bailón, Camuesco, Olivares, Xaus, Zarzuelo and Gálvez2), which documents a preventive effect of Lactobacillus fermentum in a murine model of septic shock, provides important clues as to what these mechanisms might be. The authors document markedly reduced splenic T cell responses, suggesting that the T cell compartment might be the relevant target for many of the effects observed by probiotics. Also, the earlier observation reported by the same laboratory that different probiotic bacteria, as well as prebiotics, are beneficial in a trinitrobenzenesulfonic acid model of rat colitis (which represents a classical T cell-mediated inflammation) points in this direction. Interestingly, both in vitro as well as in human volunteers or patients with Crohn's disease, Lactobacillus rhamnosus induced an anergy-like T cell hyporesponsiveness which was apparently mediated via reduced co-stimulatory activity in dendritic cells(Reference Braat, van den Brande, van Tol, Hommes, Peppelenbosch and van Deventer25), which fits well with a scheme that pre- and probiotics act through diminished T cell activation(Reference Braat, van den Brande, van Tol, Hommes, Peppelenbosch and van Deventer25). This hypothesis also proves exceedingly useful in explaining the clinical efficacy in Crohn's disease of Lactococcus lactis expressing IL-10 where intravenous application of this IL is clinically not useful(Reference Braat, Rottiers, Hommes, Huyghebaert, Remaut, Remon, van Deventer, Neirynck, Peppelenbosch and Steidler26, Reference Fukatsu, Sakamoto, Hara, Ueno, Maeshima, Matsumoto, Mochizuki and Hiraide27); the bacterial context of the IL-10 might result in combined T cell anergy and IL-10-dependent induction of tolerance and thus be synergistic. In this context it should prove highly interesting to compare the efficacy of Lactococcus lactis expressing IL-10 to the mother organism not expressing IL-10 in Crohn's disease, but such a study has not been performed.
The molecular basis of the immunological modulation by pre- and probiotics on T cell reactivity remains unaddressed, but may lie in the secretion of soluble factors interfering with dendritic cell specific intercellular adhesion molecule 3-grabbing nonintegrin (DC-SIGN)(Reference Martin, O'Sullivan, Low and Thomas28). This may provide the bacterium with an evasive strategy with respect to the immune system and hence a competitive advantage at the mucosal surface and thus provide the bacterium with a niche for cell growth in the bowel. How bacteria prevent other micro-organisms from profiting from this niche is unclear, but evidence exists, for instance, that Lactobacillus rhamnosus is able to suppress the growth of a diverse range of other bacteria via a variety of strategies(Reference Boris, Jimenez-Diaz, Caso and Barbes29–Reference Rogelj, Bogovic Matijasic, Canzek Majhenic and Stojkovic31).
Strikingly, in the recent trial of probiotics in human acute pancreatitis(Reference Besselink, van Santvoort and Buskens1) the supermortality in the probiotic-treated group seemed mainly due to enhanced bowel ischaemia in these patients. Since there is good evidence linking bowel ischaemia severity to reduced T cell reactivity(Reference Fukatsu, Sakamoto, Hara, Ueno, Maeshima, Matsumoto, Mochizuki and Hiraide27), effects of probiotic bacteria on T cell reactivity may be linked to negative effects of probiotics in this disease.
In conclusion, also based on the study by Arribas et al. (Reference Arribas, Elena Rodríguez-Cabezas, Comalada, Bailón, Camuesco, Olivares, Xaus, Zarzuelo and Gálvez2), a picture emerges in which pre- and probiotics exert a class effect on reactivity in the T cell compartment, possibly mediated via reduced co-stimulatory activity of dendritic cells. In view of this class effect, the current emphasis in the field that each different pre- and probiotic should be considered individually and that results obtained with different strains should not be extrapolated to related strains may be somewhat overemphasised. In other words, the bioanalytical profiling of both host microbiota and probiotic will be crucial for defining how best to apply prebiotics and probiotics: optimal dosage, frequency, duration, and consequently providing a rational basis for supporting the belief that their consumption results in health benefits.
The authors have no conflict of interest to declare.