Inorganic Phosphate Induces Spore Morphogenesis and Enterotoxin Production in the Intestinal Pathogen Clostridium perfringens
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感染与免疫杂志 2006年第6期
Departamento de Microbiología, Facultad de Ciencias Bioquímicas y Farmaceuticas, Universidad Nacional de Rosario-Instituto de Biología Molecular y Celular de Rosario (IBR-CONICET), Rosario, Argentina
Department of Microbiology, College of Science
Department of Biomedical Sciences, College of Veterinary Medicine, Oregon State University, Corvallis, Oregon
ABSTRACT
Clostridium perfringens enterotoxin (CPE) is an important virulence factor for food poisoning and non-food borne gastrointestinal (GI) diseases. Although CPE production is strongly regulated by sporulation, the nature of the signal(s) triggering sporulation remains unknown. Here, we demonstrated that inorganic phosphate (Pi), and not pH, constitutes an environmental signal inducing sporulation and CPE synthesis. In the absence of Pi-supplementation, C. perfringens displayed a spo0A phenotype, i.e., absence of polar septation and DNA partitioning in cells that reached the stationary phase of growth. These results received support from our Northern blot analyses which demonstrated that Pi was able to counteract the inhibitory effect of glucose at the onset of sporulation and induced spo0A expression, indicating that Pi acts as a key signal triggering spore morphogenesis. In addition to being the first study reporting the nature of a physiological signal triggering sporulation in clostridia, these findings have relevance for the development of antisporulation drugs to prevent or treat CPE-mediated GI diseases in humans.
TEXT
Clostridium perfringens is a gram-positive, anaerobic, endospore-forming bacterium causing gastrointestinal and histotoxic infections in humans and animals (2, 6, 9, 17). The virulence of this bacterium largely results from its prolific ability to produce at least 15 different toxins (18). In addition, enterotoxigenic C. perfringens isolates produce a 35-kDa enterotoxin (C. perfringens enterotoxin [CPE]), whose synthesis is under a strict positive control of sporulation (3, 5, 6, 9, 17). In C. perfringens, the production of CPE is confined to the large compartment (mother cell) of the sporangium where cpe transcription is believed to be driven from the mother cell-specific forms of the RNA polymerase, RNA-E and RNA-K (30). The copious amount of CPE (as much as 10% or more of the total protein of the developing sporangium) is accumulated probably only in the cytoplasm of the mother cell compartment until its release when the mother cell lyses at the completion of sporulation to liberate the mature spore (17). The released CPE rapidly binds to protein receptors present on the apical surface of enterocytes and induces cell permeabilization with the concomitant appearance of the symptoms of enterotoxaemia, intestinal cramping, and diarrhea (2, 17, 18).
Despite the key role of spores in CPE synthesis and in the dissemination and developing of clostridial diseases, very little is known at the molecular level about the regulatory mechanisms governing the formation of spores in clostridia (6, 9, 11, 13, 20, 23). Although from genome sequence analyses it can be assumed that the mechanism of spore formation in Bacillus and Clostridium is conserved (21, 24, 25), the main differences reside at the level of the initiation of the sporulation process (24, 25). While orthologs for spo0A and the genes activated by Spo0AP, along with most of the spo genes that are subsequently expressed during the morphogenesis of the spore, are present in all the sequenced Clostridium species, the genes involved in the activation of Spo0A (phosphorelay genes and their regulators) seem to be absent in clostridia (10, 24, 25). The only spo0 gene found in clostridia is spo0A, and therefore it constitutes the unique shared gene of Bacillus and Clostridium that is clearly involved in the initiation of sporulation in both genera (11, 24).
In this work, we investigated the nature of putative environmental and/or metabolic signals (15) that regulate the commitment of vegetative cells of C. perfringens to sporulate and the production of CPE. Examining the growth of C. perfringens in Duncan strong sporulation medium (DSSM; 0.4% yeast extract, 1.5% proteose peptone, 0.4% soluble starch, 1% Na2HPO4 · 7H2O, and 0.1% sodium thioglycolate) (4), it is possible to appreciate that during the logarithmic phase of growth there is a net decrease in pH that is stabilized with the appearance of mature spores (4 and data not shown). In DSSM, the pH is regulated by the addition of Na2HPO4 (inorganic phosphate [Pi]) at a final concentration close to 35 mM. This concentration of Pi in a complex growth medium is unusually high, taking into consideration the nutritional requirement (micromolar amounts) of a bacterial culture for this ion (1, 22, 31). Therefore, one parameter that might regulate the formation of spores in DSSM would be the pH and/or the supplemented Pi.
In order to determine whether Pi and/or pH regulates the capacity of C. perfringens to form spores, we grew C. perfringens strain SM101 (30) in a modified DSSM (Duncan strong modified medium [DSMM]) supplemented with different concentrations of Na2HPO4. As shown in Table 1, at supplemented Pi concentrations of 3 mM or less, the efficiency of sporulation was almost zero. However, the growth of C. perfringens was not ameliorated in DSMM without Pi supplementation since the rate of growth was higher in DSMM than that in DSSM (data not shown). Moreover, for the DSMM cultures the exponential phase continued for a couple of hours before reaching the stationary phase of growth in comparison with cultures developed in regular DSSM or DSMM supplemented with 35 mM Pi (data not shown). The final cellular yield was always consistently higher in DSMM (without Pi supplementation) than in DSSM (an average of 4 x 108 CFU/ml versus 2 x 107 CFU/ml) (Table 1). Therefore, the absence of exogenous Pi supplementation in DSMM had no effect on vegetative growth of C. perfringens but blocked, during the stationary phase, the differentiation into spores.
In contrast, while 3 mM Pi did not induce sporulation, C. perfringens started to sporulate efficiently with the addition of Pi at a final concentration of 5 mM (Table 1). Interestingly, the culture with Pi concentrations between 5 mM and 50 mM did not affect growth and yielded a maximal number of spores (Table 1). Consistent with these results, we detected a high production of CPE after 5 h of growth in DSMM supplemented with exogenous Pi, while no CPE production was detected in non-Pi-supplemented cultures at any stage of growth (Fig. 1). Higher concentrations of Pi (more than 60 mM) reduced the final cellular and spore yields, suggesting some toxic effect of high concentrations of Pi on growth. These results indicated that there is an optimum range of Pi levels for spore formation and suggests, for the first time, that sporulation of C. perfringens can be positively regulated by soluble Pi (Table 1).
It can be supposed that Pi did not constitute a nutritional signal because the basal Pi concentration in DSMM, without Pi supplementation, is close to 2 mM, which is at least 100-fold higher than that required for bacterial growth (1, 22, 31). Reinforcing the view that Pi is not a nutritional signal for sporulation, we found that the consumption of Pi after the overnight growth of C. perfringens from cultures with or without Pi supplementation was negligible in comparison with the initial concentrations of the anion (data not shown).
In order to distinguish whether the observed effects on spore formation and CPE production were due to the presence of Pi by itself or the regulation of pH by its buffering capacity, we performed an experiment similar to the one described above using DSMM in the absence of Pi supplementation but in the presence of different concentrations of Tris or morpholinepropanesulfonic acid (MOPS) to regulate the pH of the medium (DSMM-Tris or DSMM-MOPS). As observed in Fig. 2, C. perfringens cultures grown in DSMM-Tris (or DSMM-MOPS; data not shown) produced similar cellular yields and final pH values as those obtained after growth in DSMM supplemented with different concentrations of Pi. However, under these experimental conditions (growth in DSMM-Tris or DSMM-MOPS without Pi supplementation), C. perfringens was unable to sporulate (Fig. 2). Therefore, these results clearly showed that Pi, and not pH, regulated the capacity of C. perfringens cells to differentiate into spores.
We then hypothesized that Pi would constitute a universal signal to induce sporulation and CPE synthesis under different growth conditions. To test this hypothesis, we recurred to the use of TGY (tryptone, glucose, and yeast extract) medium and fluid thioglycolate medium (FTG), two rich media commonly used for the vegetative growth of C. perfringens where spore formation is completely impaired (3, 11, 20, 30). The intrinsic Pi concentration (<2 mM) in TGY and FTG medium was lower than the threshold Pi concentration (5 to 7 mM) needed to induce spore formation (Table 1). In addition, both media contain high levels of glucose (0.55% and 2.0% for FTG and TGY, respectively) that would induce catabolite repression of sporulation as previously reported (13, 26). In fact, the use of glucose (1%) in DSMM supplemented with 35 mM Pi resulted in a noticeable inhibition of spore formation (data not shown). Furthermore, the expression of cpe, measured from a reporter -glucuronidase fusion (cpe-gusA) as previously described (19), in C. perfringens cells grown in DSMM supplemented with Pi was strongly repressed in the presence of 1% glucose (Fig. 3A). However, the -glucuronidase level in DSMM supplemented with Pi and glucose was much higher than the -glucuronidase activity obtained in non-Pi-supplemented cultures after the addition of glucose (Fig. 3A). In order to avoid the Pi-independent repressive effect of glucose on C. perfringens sporulation, we omitted the addition of glucose to the formulation of TGY and FTG. Under these experimental conditions, we observed high levels of sporulation (Table 2), cpe-gusA expression (Fig. 3B), and CPE production (Fig. 3C) when glucose-free TGY and FTG (TY and FT, respectively) media were supplemented with exogenous Pi. Collectively, these results indicated that Pi by itself constitutes a universal signal for the sporulation and production of CPE in C. perfringens.
In order to determine the precise developmental stage when the presence of Pi is needed for sporulation, we analyzed the cell phenotype of C. perfringens cultures grown in DSMM or DSMM-Pi by phase-contrast microscopy as previously described (11). C. perfringens wild-type SM101 grown for 5 h in DSMM-Pi showed a great proportion of cells harboring refractile polar prespores (Fig. 4A). In contrast, strain SM101 grown in DSMM (without Pi supplementation) produced cells without any prespores (Fig. 4B). Significantly, the cell phenotype displayed by the non-Pi-supplemented culture of the wild-type cells (Fig. 4B) was indistinguishable from the Spo0– phenotype displayed by isogenic Spo0A-deficient cells (thus blocked at stage zero) grown in DSMM with or without added Pi (Fig. 4C and D). These results strongly suggested that C. perfringens cells grown in non-Pi-supplemented DSMM were blocked at stage zero of the sporulation cycle. This observation was reinforced by fluorescence microscopy analyses using the fluorescent dyes DAPI (4',6'-diamidino-2-phenylindole; specific for DNA) and FM 4-64 (specific for membrane lipids). For cells grown in Pi-supplemented medium, it was possible to delimit the membrane of the polar prespore (Fig. 4E) with the DNA of the sporangium asymmetrically compartmentalized in both developing cells (Fig. 4G, the prespore and the mother cell). In contrast, for cells from the non-Pi-supplemented cultures, DAPI staining (Fig. 4H) was homogeneous without any asymmetric DNA compartmentalization, while simultaneously the dye for the membrane lipids did not denote any polar membrane (Fig. 4F). These results confirmed that the Pi signal was required at a very early stage of the development of the spore and strongly suggested that Pi would constitute a sporulation signal acting at the onset of the developmental process before asymmetric division (stage zero).
As indicated earlier, one important requirement for the onset of the sporulation is that sporulation-committed cells induce the expression of spo0A (8, 10, 23, 24, 25). Therefore, the level of spo0A expression seems to be a valid tool to determine whether a C. perfringens culture has initiated the formation of spores beyond stage zero. Northern blotting experiments (11), by detecting the amount of the specific messenger RNA (mRNA) for spo0A, confirmed that under conditions of supplementation with exogenous Pi the amount of spo0A mRNA far exceeded (20- to 50-fold) the levels of spo0A mRNA detected under growth conditions of non-Pi supplementation (Fig. 5, lanes 1 to 4). Thus, these results strongly suggested that Pi acted as a positive signal at the initiation of the sporulation process (stage zero, induced expression of spo0A). Furthermore, if this is the situation, Pi should be able to compete with negative sporulation signals acting at the onset of the developmental process (repression of spo0A expression). For instance, the blockage of sporulation at stage zero, once a culture has reached the end of the vegetative growth, can be produced by the addition of glucose (catabolite repression of sporulation). In accord with our hypothesis (Fig. 5, lanes 5 to 6), the addition of Pi in a C. perfringens culture grown in TGY medium was able (at least partially) to counteract the inhibitory glucose effect on spo0A transcription (10, 23, 24, 26) and strongly supports the notion of Pi as a positive environmental signal acting at stage zero of sporulation.
C. perfringens colonizes the small intestine of human and animal where, by unknown mechanisms, it differentiates into spores with the concomitant production of CPE, and then CPE-associated gastrointestinal disorders develop (17). In this regard, one important question arises regarding in vivo significance of Pi as a physiological signal triggering sporulation and CPE production in C. perfringens. The intestines represent open environments with plentiful nutrients that support the growth of approximately 500 different bacterial species to the level of 1 x 108 to 1 x 1010 CFU/ml (7). It is possible that sporulation may represent an adaptive response (15) for C. perfringens to survive in the stressful environment of the intestine (normal flora, microbicide peptides, bile salts, etc.) rather than a response to a food deficiency, an opposite situation to the regulation of sporulation in B. subtilis where unknown signals linked to nutrient starvation induce spore formation (10). It has been estimated from metabolic balance studies that in healthy adults consuming an average Western diet, a Pi concentration of 15 to 30 mM is normally present under homeostatic conditions in the human intestinal lumen (12, 14, 27, 28). This level of in vivo Pi concentration, as we demonstrated in this study, should be able to induce sporulation and CPE production in C. perfringens. It is also interesting to note that in all the known Pi-sensing systems reported in bacteria, Pi limitation is the signal that triggers adaptation (29). For instance, the phoP-phoR regulatory systems, present in a diverse range of bacteria but apparently absent in C. perfringens (21), are activated by depletion of Pi to micromolar levels (1, 16, 22, 31). We demonstrated in this study that an excess amount of Pi, but not Pi starvation, induces the developmental adaptation (sporulation) of C. perfringens. Further research on the identification of the signal regulatory system that recognizes millimolar levels of soluble Pi as an environmental signal to induce the initiation of sporulation should help in understanding the mechanism of developmental adaptation of C. perfringens.
ACKNOWLEDGMENTS
This research was supported by grants from the International Foundation for Science (E/2936-2), Fundacion Antorchas (14022-57), FONCyT (PICT-01-11651), and CONICET (3052) (to R.G.) and U.S. Department of Agriculture grant 2002-02281 from the Ensuring Food Safety Research Program (to M.R.S.).
We specially thank Stephen Melville (Virginia Polytechnic and State University, Department of Biology) for the generous provision of the cpe-gusA reporter fusion. We also thank Bruce McClane (University of Pittsburgh, School of Medicine) for providing us with CPE antibody.
V.A.P. and M.B.M. are doctoral fellows of CONICET. R.R.G. is a career member of CONICET, a former Pew Latin American Scholar (San Francisco, CA), and Fulbright International Scholar (Washington, D.C.).
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Department of Microbiology, College of Science
Department of Biomedical Sciences, College of Veterinary Medicine, Oregon State University, Corvallis, Oregon
ABSTRACT
Clostridium perfringens enterotoxin (CPE) is an important virulence factor for food poisoning and non-food borne gastrointestinal (GI) diseases. Although CPE production is strongly regulated by sporulation, the nature of the signal(s) triggering sporulation remains unknown. Here, we demonstrated that inorganic phosphate (Pi), and not pH, constitutes an environmental signal inducing sporulation and CPE synthesis. In the absence of Pi-supplementation, C. perfringens displayed a spo0A phenotype, i.e., absence of polar septation and DNA partitioning in cells that reached the stationary phase of growth. These results received support from our Northern blot analyses which demonstrated that Pi was able to counteract the inhibitory effect of glucose at the onset of sporulation and induced spo0A expression, indicating that Pi acts as a key signal triggering spore morphogenesis. In addition to being the first study reporting the nature of a physiological signal triggering sporulation in clostridia, these findings have relevance for the development of antisporulation drugs to prevent or treat CPE-mediated GI diseases in humans.
TEXT
Clostridium perfringens is a gram-positive, anaerobic, endospore-forming bacterium causing gastrointestinal and histotoxic infections in humans and animals (2, 6, 9, 17). The virulence of this bacterium largely results from its prolific ability to produce at least 15 different toxins (18). In addition, enterotoxigenic C. perfringens isolates produce a 35-kDa enterotoxin (C. perfringens enterotoxin [CPE]), whose synthesis is under a strict positive control of sporulation (3, 5, 6, 9, 17). In C. perfringens, the production of CPE is confined to the large compartment (mother cell) of the sporangium where cpe transcription is believed to be driven from the mother cell-specific forms of the RNA polymerase, RNA-E and RNA-K (30). The copious amount of CPE (as much as 10% or more of the total protein of the developing sporangium) is accumulated probably only in the cytoplasm of the mother cell compartment until its release when the mother cell lyses at the completion of sporulation to liberate the mature spore (17). The released CPE rapidly binds to protein receptors present on the apical surface of enterocytes and induces cell permeabilization with the concomitant appearance of the symptoms of enterotoxaemia, intestinal cramping, and diarrhea (2, 17, 18).
Despite the key role of spores in CPE synthesis and in the dissemination and developing of clostridial diseases, very little is known at the molecular level about the regulatory mechanisms governing the formation of spores in clostridia (6, 9, 11, 13, 20, 23). Although from genome sequence analyses it can be assumed that the mechanism of spore formation in Bacillus and Clostridium is conserved (21, 24, 25), the main differences reside at the level of the initiation of the sporulation process (24, 25). While orthologs for spo0A and the genes activated by Spo0AP, along with most of the spo genes that are subsequently expressed during the morphogenesis of the spore, are present in all the sequenced Clostridium species, the genes involved in the activation of Spo0A (phosphorelay genes and their regulators) seem to be absent in clostridia (10, 24, 25). The only spo0 gene found in clostridia is spo0A, and therefore it constitutes the unique shared gene of Bacillus and Clostridium that is clearly involved in the initiation of sporulation in both genera (11, 24).
In this work, we investigated the nature of putative environmental and/or metabolic signals (15) that regulate the commitment of vegetative cells of C. perfringens to sporulate and the production of CPE. Examining the growth of C. perfringens in Duncan strong sporulation medium (DSSM; 0.4% yeast extract, 1.5% proteose peptone, 0.4% soluble starch, 1% Na2HPO4 · 7H2O, and 0.1% sodium thioglycolate) (4), it is possible to appreciate that during the logarithmic phase of growth there is a net decrease in pH that is stabilized with the appearance of mature spores (4 and data not shown). In DSSM, the pH is regulated by the addition of Na2HPO4 (inorganic phosphate [Pi]) at a final concentration close to 35 mM. This concentration of Pi in a complex growth medium is unusually high, taking into consideration the nutritional requirement (micromolar amounts) of a bacterial culture for this ion (1, 22, 31). Therefore, one parameter that might regulate the formation of spores in DSSM would be the pH and/or the supplemented Pi.
In order to determine whether Pi and/or pH regulates the capacity of C. perfringens to form spores, we grew C. perfringens strain SM101 (30) in a modified DSSM (Duncan strong modified medium [DSMM]) supplemented with different concentrations of Na2HPO4. As shown in Table 1, at supplemented Pi concentrations of 3 mM or less, the efficiency of sporulation was almost zero. However, the growth of C. perfringens was not ameliorated in DSMM without Pi supplementation since the rate of growth was higher in DSMM than that in DSSM (data not shown). Moreover, for the DSMM cultures the exponential phase continued for a couple of hours before reaching the stationary phase of growth in comparison with cultures developed in regular DSSM or DSMM supplemented with 35 mM Pi (data not shown). The final cellular yield was always consistently higher in DSMM (without Pi supplementation) than in DSSM (an average of 4 x 108 CFU/ml versus 2 x 107 CFU/ml) (Table 1). Therefore, the absence of exogenous Pi supplementation in DSMM had no effect on vegetative growth of C. perfringens but blocked, during the stationary phase, the differentiation into spores.
In contrast, while 3 mM Pi did not induce sporulation, C. perfringens started to sporulate efficiently with the addition of Pi at a final concentration of 5 mM (Table 1). Interestingly, the culture with Pi concentrations between 5 mM and 50 mM did not affect growth and yielded a maximal number of spores (Table 1). Consistent with these results, we detected a high production of CPE after 5 h of growth in DSMM supplemented with exogenous Pi, while no CPE production was detected in non-Pi-supplemented cultures at any stage of growth (Fig. 1). Higher concentrations of Pi (more than 60 mM) reduced the final cellular and spore yields, suggesting some toxic effect of high concentrations of Pi on growth. These results indicated that there is an optimum range of Pi levels for spore formation and suggests, for the first time, that sporulation of C. perfringens can be positively regulated by soluble Pi (Table 1).
It can be supposed that Pi did not constitute a nutritional signal because the basal Pi concentration in DSMM, without Pi supplementation, is close to 2 mM, which is at least 100-fold higher than that required for bacterial growth (1, 22, 31). Reinforcing the view that Pi is not a nutritional signal for sporulation, we found that the consumption of Pi after the overnight growth of C. perfringens from cultures with or without Pi supplementation was negligible in comparison with the initial concentrations of the anion (data not shown).
In order to distinguish whether the observed effects on spore formation and CPE production were due to the presence of Pi by itself or the regulation of pH by its buffering capacity, we performed an experiment similar to the one described above using DSMM in the absence of Pi supplementation but in the presence of different concentrations of Tris or morpholinepropanesulfonic acid (MOPS) to regulate the pH of the medium (DSMM-Tris or DSMM-MOPS). As observed in Fig. 2, C. perfringens cultures grown in DSMM-Tris (or DSMM-MOPS; data not shown) produced similar cellular yields and final pH values as those obtained after growth in DSMM supplemented with different concentrations of Pi. However, under these experimental conditions (growth in DSMM-Tris or DSMM-MOPS without Pi supplementation), C. perfringens was unable to sporulate (Fig. 2). Therefore, these results clearly showed that Pi, and not pH, regulated the capacity of C. perfringens cells to differentiate into spores.
We then hypothesized that Pi would constitute a universal signal to induce sporulation and CPE synthesis under different growth conditions. To test this hypothesis, we recurred to the use of TGY (tryptone, glucose, and yeast extract) medium and fluid thioglycolate medium (FTG), two rich media commonly used for the vegetative growth of C. perfringens where spore formation is completely impaired (3, 11, 20, 30). The intrinsic Pi concentration (<2 mM) in TGY and FTG medium was lower than the threshold Pi concentration (5 to 7 mM) needed to induce spore formation (Table 1). In addition, both media contain high levels of glucose (0.55% and 2.0% for FTG and TGY, respectively) that would induce catabolite repression of sporulation as previously reported (13, 26). In fact, the use of glucose (1%) in DSMM supplemented with 35 mM Pi resulted in a noticeable inhibition of spore formation (data not shown). Furthermore, the expression of cpe, measured from a reporter -glucuronidase fusion (cpe-gusA) as previously described (19), in C. perfringens cells grown in DSMM supplemented with Pi was strongly repressed in the presence of 1% glucose (Fig. 3A). However, the -glucuronidase level in DSMM supplemented with Pi and glucose was much higher than the -glucuronidase activity obtained in non-Pi-supplemented cultures after the addition of glucose (Fig. 3A). In order to avoid the Pi-independent repressive effect of glucose on C. perfringens sporulation, we omitted the addition of glucose to the formulation of TGY and FTG. Under these experimental conditions, we observed high levels of sporulation (Table 2), cpe-gusA expression (Fig. 3B), and CPE production (Fig. 3C) when glucose-free TGY and FTG (TY and FT, respectively) media were supplemented with exogenous Pi. Collectively, these results indicated that Pi by itself constitutes a universal signal for the sporulation and production of CPE in C. perfringens.
In order to determine the precise developmental stage when the presence of Pi is needed for sporulation, we analyzed the cell phenotype of C. perfringens cultures grown in DSMM or DSMM-Pi by phase-contrast microscopy as previously described (11). C. perfringens wild-type SM101 grown for 5 h in DSMM-Pi showed a great proportion of cells harboring refractile polar prespores (Fig. 4A). In contrast, strain SM101 grown in DSMM (without Pi supplementation) produced cells without any prespores (Fig. 4B). Significantly, the cell phenotype displayed by the non-Pi-supplemented culture of the wild-type cells (Fig. 4B) was indistinguishable from the Spo0– phenotype displayed by isogenic Spo0A-deficient cells (thus blocked at stage zero) grown in DSMM with or without added Pi (Fig. 4C and D). These results strongly suggested that C. perfringens cells grown in non-Pi-supplemented DSMM were blocked at stage zero of the sporulation cycle. This observation was reinforced by fluorescence microscopy analyses using the fluorescent dyes DAPI (4',6'-diamidino-2-phenylindole; specific for DNA) and FM 4-64 (specific for membrane lipids). For cells grown in Pi-supplemented medium, it was possible to delimit the membrane of the polar prespore (Fig. 4E) with the DNA of the sporangium asymmetrically compartmentalized in both developing cells (Fig. 4G, the prespore and the mother cell). In contrast, for cells from the non-Pi-supplemented cultures, DAPI staining (Fig. 4H) was homogeneous without any asymmetric DNA compartmentalization, while simultaneously the dye for the membrane lipids did not denote any polar membrane (Fig. 4F). These results confirmed that the Pi signal was required at a very early stage of the development of the spore and strongly suggested that Pi would constitute a sporulation signal acting at the onset of the developmental process before asymmetric division (stage zero).
As indicated earlier, one important requirement for the onset of the sporulation is that sporulation-committed cells induce the expression of spo0A (8, 10, 23, 24, 25). Therefore, the level of spo0A expression seems to be a valid tool to determine whether a C. perfringens culture has initiated the formation of spores beyond stage zero. Northern blotting experiments (11), by detecting the amount of the specific messenger RNA (mRNA) for spo0A, confirmed that under conditions of supplementation with exogenous Pi the amount of spo0A mRNA far exceeded (20- to 50-fold) the levels of spo0A mRNA detected under growth conditions of non-Pi supplementation (Fig. 5, lanes 1 to 4). Thus, these results strongly suggested that Pi acted as a positive signal at the initiation of the sporulation process (stage zero, induced expression of spo0A). Furthermore, if this is the situation, Pi should be able to compete with negative sporulation signals acting at the onset of the developmental process (repression of spo0A expression). For instance, the blockage of sporulation at stage zero, once a culture has reached the end of the vegetative growth, can be produced by the addition of glucose (catabolite repression of sporulation). In accord with our hypothesis (Fig. 5, lanes 5 to 6), the addition of Pi in a C. perfringens culture grown in TGY medium was able (at least partially) to counteract the inhibitory glucose effect on spo0A transcription (10, 23, 24, 26) and strongly supports the notion of Pi as a positive environmental signal acting at stage zero of sporulation.
C. perfringens colonizes the small intestine of human and animal where, by unknown mechanisms, it differentiates into spores with the concomitant production of CPE, and then CPE-associated gastrointestinal disorders develop (17). In this regard, one important question arises regarding in vivo significance of Pi as a physiological signal triggering sporulation and CPE production in C. perfringens. The intestines represent open environments with plentiful nutrients that support the growth of approximately 500 different bacterial species to the level of 1 x 108 to 1 x 1010 CFU/ml (7). It is possible that sporulation may represent an adaptive response (15) for C. perfringens to survive in the stressful environment of the intestine (normal flora, microbicide peptides, bile salts, etc.) rather than a response to a food deficiency, an opposite situation to the regulation of sporulation in B. subtilis where unknown signals linked to nutrient starvation induce spore formation (10). It has been estimated from metabolic balance studies that in healthy adults consuming an average Western diet, a Pi concentration of 15 to 30 mM is normally present under homeostatic conditions in the human intestinal lumen (12, 14, 27, 28). This level of in vivo Pi concentration, as we demonstrated in this study, should be able to induce sporulation and CPE production in C. perfringens. It is also interesting to note that in all the known Pi-sensing systems reported in bacteria, Pi limitation is the signal that triggers adaptation (29). For instance, the phoP-phoR regulatory systems, present in a diverse range of bacteria but apparently absent in C. perfringens (21), are activated by depletion of Pi to micromolar levels (1, 16, 22, 31). We demonstrated in this study that an excess amount of Pi, but not Pi starvation, induces the developmental adaptation (sporulation) of C. perfringens. Further research on the identification of the signal regulatory system that recognizes millimolar levels of soluble Pi as an environmental signal to induce the initiation of sporulation should help in understanding the mechanism of developmental adaptation of C. perfringens.
ACKNOWLEDGMENTS
This research was supported by grants from the International Foundation for Science (E/2936-2), Fundacion Antorchas (14022-57), FONCyT (PICT-01-11651), and CONICET (3052) (to R.G.) and U.S. Department of Agriculture grant 2002-02281 from the Ensuring Food Safety Research Program (to M.R.S.).
We specially thank Stephen Melville (Virginia Polytechnic and State University, Department of Biology) for the generous provision of the cpe-gusA reporter fusion. We also thank Bruce McClane (University of Pittsburgh, School of Medicine) for providing us with CPE antibody.
V.A.P. and M.B.M. are doctoral fellows of CONICET. R.R.G. is a career member of CONICET, a former Pew Latin American Scholar (San Francisco, CA), and Fulbright International Scholar (Washington, D.C.).
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