Growth and Survival of Campylobacter Pathogens in the Presence of Different Metabolic Inhibitors
Abstract:
The effect of metabolic inhibitors on the growth of Campylobacter (100 human, animal and environmental isolates) was investigated. These inhibitors included β-fluoropyruvate (FP), iodoacetate (IAA, an inhibitor of gylcolysis) and α-methyl-D-glucoside (MG, a glucose analogue). In the presence of FP (0.8-1 g L-1), the growth C. jejuni was inhibited for 24 h then growth occurred efficiently. However, the growth of C. coli was reduced by more than 50% even after 72 h. The growth of C. dolyei was totally inhibited by the FP concentrations employed. In the presence of IAA (0.0048 g L-1), non of the tested species was able to grow; when half of the IAA concentration was used, C. coli grew after 24 h whereas C. jejuni grew after 48 h. On the other hand, C. dolyei was unable to grow even after 72 h. All the strains tested were relatively resistant to high concentration of MG; the growth of C. jejuni and C. doylei was completely inhibited in the presence of 50 and 40 g L-1 of MG whereas C. coli was resistant to MG concentration (70 g L-1) when grown in brain heart infusion medium. This investigation attempts to not only understand better the survival of the organism in the environment but also should assist in finding ways to control Campylobacter in the environment and the food chain and hence reduce the risk of infection to human beings.
Growth and Survival of Campylobacter Pathogens in the Presence of Different Metabolic Inhibitors
. Journal of Medical Sciences, 8: 262-268.
INTRODUCTION
Campylobacter species are Gram negative, microaerophilic and/or anaerobic, mainly spiral shaped, bacteria that have a wide range of diversity regarding natural habitats, potential for disease production and procedures for isolation and culturing (Penner and Mills, 1997). Campylobacter species can be found as commensal microflora or pathogen in the intestinal tracts of birds, animals or human, human oral cavity and in the genital tract of animals (Tenoverand and Fennell, 1992; Harvey et al., 2003). Also, Campylobacter has been isolated from fresh water and seawater (Terzieva and McFeters, 1991; Moore et al., 2002; Cools et al., 2003) and from shellfish (Sails et al., 2003).
Campylobacters vary in producing disease such as diarrhoea, bacteraemia, septic abortion, infertility and possibly disease of human teeth (MacLaren and Agumbah, 1988; Abderhalden et al., 1995; Akiba et al., 2002; Belongia et al., 2003; Patel et al., 2003). Since 1981, Campylobacter have been the most commonly reported cause of human gastro-intestinal illness in England and Wales (Frost et al., 2002). In addition, in a small minority of patients who are infected with a particular serotype of C. jejuni may develop Guillain-Barre` syndrome (Ogawara et al., 2003), Miller-Fisher syndrome (Ang et al., 2002) or reactive arthritis (Soderlin et al., 2003). The handling or consumption of raw or undercooked meat products and occasionally contaminated water or raw milk, can be considered as main vehicles for campylobacteriosis transmission (Sopwith et al., 2003). A number of species may be involved in human disease, but the majority of cases are caused by C. jejuni (Frost et al., 2002). In addition, campylobacters are varied in their requirements for growth, composition of the medium, temperature and atmospheric conditions. All Campylobacter species utilise organic amino acids or citric acid cycle intermediates to obtain energy and non-of them ferment or oxidise carbohydrates (Smibert, 1978).
Campylobacters have been classified and reclassified as the progress of research into the organism has advanced. Currently, the genus Campylobacter contains 16 species and 6 subspecies. Recently, Penner and Mills (1997) reviewed and divided Campylobacter species into three groups on the basis of the optimum temperature for growth, the habitat and the diseases associated with the organism. These groups included thermophilic enteropathogenic species, animal pathogens and commensals that may infect human and species associated with periodontal disease.
Until 1973, it was unknown that this group is the most important agent linked to diarrhoeal disease in humans. However, the true significance of Campylobacter to human health was established in 1977 when a selective medium was designed for their isolation (Skirrow, 1977). Since that time, it was found that all the members of this group are pathogenic and rarely recovered from healthy humans (On, 2001; Belongia et al., 2003). Thermophilic Campylobacter species, particularly, C. jejuni and C. coli are now recognised as the most common causative agents of bacterial gastroenteritis in humans (Coker et al., 2002; Frost et al., 2002; Belongia et al., 2003; Sandberg et al., 2006; Hansson et al., 2007). In developing countries, the highest incidence is in infants and young children (Ketley, 1997; Coker et al., 2002; Fullerton et al., 2007) whereas in developed countries young adults are mostly the targets, aged 18-29 years old (Rosenquist et al., 2003).
Campylobacter spp. continue to be the greatest cause of bacterial gastrointestinal infections in humans worldwide. Some foodborne pathogens tend to be widely distributed in the environment and have different means of surviving and being transmitted to different hosts. Therefore, multi intervention strategies may be required to successfully reduce the risk of food pathogens in poultry, livestock and humans. Because of its impact on human and animal health, this preliminary study is aimed at trying to reduce the incidence of Campylobacter in the environment and possibly through the food chain.
MATERIALS AND METHODS
Bacterial strains: The strains tested were type strains (C. jejuni. subsp. jejuni NCTC 11168, C. jejuni. subsp. dolyei NCTC 11951 and C. coli NCTC 11366) obtained from the National Collection of Type Culture, Colindale, UK, human clinical isolates (80 isolates) and animal, poultry and environmental isolates (10 C. jejuni and 7 C. coli). Upon receipt, all the strains were grown on Preston medium (Oxoid), for 48-72 h at 37°C under microaerobic conditions (5% O2, 10% CO2, 85% N2, CampyGenTM Oxoid) (Bolton et al., 1997). Typical Campylobacter colonies were subcultured in brain heart infusion (BHI) broth medium (Oxoid) and incubated under similar conditions. The resulting cultures were dispensed into cryotubes containing 14-20% glycerol and kept at -70°C for further use.
Campylobacter strains were identified by Gram stain, morphology and conventional biochemical tests, API Campy or hippurate test, nitrate reduction, catalase and oxidase tests.
Culture media
Brain heart infusion broth medium: Brain Heart Infusion (BHI) (Oxoid, CM225) is a nutritionally complex rich medium, originally devised for the growth of fastidious bacteria. The cells grown in BHI were used to study the effect of biochemical inhibitors on the growth and metabolism of Campylobacter. The medium was prepared as described by the manufacturer and was autoclaved at 15 lbs per square inch (psi), equivalent to 121°C for 15 min.
Basal medium: Basal medium was used to study the effect of different concentrations of glucose, glucose analogue on the growth of Campylobacter strains. The composition of this medium was as follows: Trypticase 20 g L-1, Yeast extract 2 g L-1, Sodium bisulphite 0.1 g L-1, Sodium chloride 5 g L-1, pH 7.4. The medium was sterilised by autoclaving as above.
Assessment of growth optical density measurements: Optical Density (OD) was used to measure the growth of organisms in broth medium (basal and BHI medium). The OD was measured using Gallenkamp Visi-spectrophotometer using 600nm filter. At different time intervals, a sample was taken from growing organisms in the medium with or without the biochemical inhibitor. The OD600nm of each sample was measured and the growth pattern was established.
RESULTS AND DISCUSSION
Effect of β-fluoropyruvate (FP) on the growth of Campylobacter species in broth media: The effect of FP on the growth of C. jejuni and C. coli, in broth media, was varied (Fig. 1-2). The inhibitory effect was observed at 0.8-1 g L-1. FP inhibited the growth of C. jejuni, but growth subsequently occurred, efficiently, within 24 h (Fig. 1). On the other hand, a marked inhibitory effect of FP on growth of C. coli (more than 50% reduction) was constant after 72 h incubation at 37°C (Fig. 2). Whereas the growth of C. subsp. doylei was completely inhibited for even more than 96 h (Fig. 3). These results indicated variability in the resistance between C. jejuni subsp. jejuni and C. coli to FP. C. jejuni adapted to grow well in the presence of 0.8 to 1 g L-1 FP after 24 h incubation, whereas the reduction in the growth of C. coli was steady for 72 h in the presence of the same concentrations of the inhibitor (Fig. 1-2). In contrast, C. subsp. doylei was extremely sensitive and the growth was inhibited even for more than 96 h (Fig. 3).
The inhibitory effects of β-fluoropyruvate on the growth of Campylobacter strains may be due to the binding of the FP to the TPP component of pyruvate oxidoreductase and consequently inactivate this enzyme.
The results showed that both of C. jejuni and C. coli are
relatively resistant to FP. However, the initial effects of
| Fig. 1: | Effect of various concentrations of β-fluoropyruvate (FP) on the growth of C. jejuni NCTC type strain (11168). Growth was measured by optical density (OD), (♦): growth with out FP 0; (■): growth with FP 0.2 g L-1; (▲): growth with FP 0.4 g L-1; (x): growth with FP 0.8 g L-1 |
| Fig. 2: | Effect of various concentrations of β-fluoropyruvate (FP) on the growth of C. coli NCTC type strain (11366). Growth was measured by optical density (OD), (♦): growth without FP; (■): growth with FP 0.2 g L-1; (▲): growth with FP 0.4 g L-1; (x): growth with FP 0.8 g L-1; (○): growth with FP 1 g L-1 |
FP (0.8-1 g L-1) on strains tested suggested that FP may have
inhibitory effects on the metabolic pathways of these organisms. In addition,
the differences in the period of the initial inhibition effects on the
growth of Campylobacter species (24 h for C. jejuni and
72 h for C. coli and more than 96 h for C. jejuni
subsp. doylei) suggested that these species may have different
| Fig. 3: | Effect of various concentrations of β-fluoropyruvate (FP) on the growth of C. dolyei NCTC type strain (11951). Growth was measured by optical density (OD), (♦): growth without FP; (■): growth with FP 0.2 g L-1; (▲): growth with FP 0.4 g L-1; (x): growth with FP 0.8 g L-1 |
metabolic pathways for pyruvate. On the other hand, the significant sensitivity of C. jejuni subsp. doylei to FP can distinguish it from C. jejuni subsp. jejuni and C. coli. The data presented are representative of a total of 100 strains tested.
Effect of iodoacetate (IAA) on the growth of Campylobacter species in broth medium: The effect of IAA on the growth of Campylobacter species was studied in broth medium. None of the tested species was able to grow in the presence of IAA at concentration of 0.0048 g L-1 (Fig. 4-6). However, varied effect of IAA at concentration of 0.0024 g L-1 on the growth of Campylobacter species was noted (Fig. 4-6). C. coli was able to grow, in the presence 0.0024 g L-1 of IAA, after 24 h of incubation, whereas C. jejuni was able to grow after 48 h in the presence of the same concentration of IAA. On the other hand, C. doylei was unable to grow even after 72 h (Fig. 6).
Since the glycolytic enzyme, glyceraldehydes 3-phosphate dehydrogenase,
is the presumed target for IAA, it was envisaged that non fermentative
organisms or those which do not oxidise glucose would not be susceptible
to the inhibitory effects of IAA. However, this was not the case in this
study. All Campylobacter species tested were relatively sensitive
to IAA. This suggests that iodoacetate may inhibit glucose synthesis pathway
(gluconeogenessis) in these organisms. All the enzymes of glucose synthesis
pathway
| Fig. 4: | Effect of various concentrations of iodoacetic acid (IAA) on the growth of C. jejuni NCTC type strain (11168). Growth was measured by optical density (OD), (♦): growth without IAA; (■): growth with IAA 0.0024 g L-1; (▲): growth with IAA 0.0048 g L-1; (x): growth with IAA 0.0096 g L-1 |
| Fig. 5: | Effect of various concentrations of iodoacetic acid (IAA) on the growth of C. coli NCTC type strain (11366). Growth was measured by optical density (OD), (♦): growth without IAA; (■): growth with IAA 0.0024 g L-1; (▲): growth with IAA 0.0048 g L-1; (x): growth with IAA 0.0096 g L-1 |
have been demonstrated in Campylobacter including glyceraldehydes
3-phosphate dehydrogenase (Wang, 1975; Parkhill et al., 2000).
The variation in the inhibitory effects on the growth of Campylobacter
species, in the lag phase, at low concentration of IAA (Fig.
4-6) might
| Fig. 6: | Effect of various concentrations of iodoacetic acid (IAA) on the growth of C. dolyei NCTC type strain (11951). Growth was measured by optical density (OD), (♦): growth without IAA; (■): growth with IAA 0.0024 g L-1; (▲): growth with IAA 0.0048 g L-1; (x): growth with IAA 0.0096 g L-1 |
be useful in the development of diagnostic tests or to improve selective media. In addition, these results suggest that Campylobacter species (C. coli and C. jejuni) may have inducible enzymes, which may become active and enable these organisms to adapt and grow under stressed conditions. The results also showed that such supposed enzymes were varied in their response to the presence of IAA.
Effect of α-methyl-D-glucoside (MG) on the growth of Campylobacter species in broth medium: All the strains tested were relatively resistant to high concentration of MG. However, the resistance to MG was varied amongst Campylobacter species (Fig. 7-9). Whereas C. coli was resistant to MG concentration of 70 g L-1, the growth of C. doylei and C. jejuni was completely inhibited in the presence of 40 and 50 g L-1 of MG, respectively (the growth was in BHI medium).
The susceptibility of Campylobacter to MG was investigated in three types of media containing different amounts of glucose (BHI containing glucose, glucose free BHI and glucose free basal medium).
The susceptibility of strains tested would be increased in medium containing lowest level of glucose. To the contrary, decreased glucose concentration resulted in a marked increase in resistance to MG.
In glucose-free BHI medium, the resistance of all strains tested was
markedly increased (Fig. 8). These
| Fig. 7: | Effect of various concentrations of α-methyl-D-glucoside (MG) on the growth of C. jejuni NCTC type strain (11168) in brain heart infusion liquid medium. Growth was measured by optical density (OD), (♦): growth without MG; (■): growth with MG 10 g L-1; (x): growth with MG 30 g L-1; (○): growth with MG 40 g L-1; (▲): growth with MG 50 g L-1 |
| Fig. 8: | Effect of various concentrations of α-methyl-D-glucoside (MG) on the growth of C. doylei NCTC type strain (11951) in brain heart infusion medium. Growth was measured by optical density (OD), (♦): growth without MG; (■): growth with MG 10 g L-1; (x): growth with MG 30 g L-1; (○): growth with MG 40 g L-1 results suggest that the inhibitory effect of high concentration of MG may be due to an increased medium osmotic pressure rather than blocking glucose transport. |
| Fig. 9: | Effect of various concentrations of α-methyl-D-glucoside (MG) on the growth of C. coli NCTC type strain (11366) in brain heart infusion medium. Growth was measured by optical density (OD), (♦): growth without MG; (■): growth with MG 10 g L-1; (x): growth with MG 30 g L-1; (○): growth with MG 40 g L-1; (▲): growth with MG 50 g L-1; (□): OD growth with MG 70 g L-1 |
The effect of increased glucose and glucose analogue concentrations on growth of C. jejuni in basal medium was also investigated (data not shown). The results indicated that the growth was delayed when glucose concentrations was increased (50 g L-1). This inhibition was the same as that caused by equivalent concentration of MG indicating that the inhibitory effect may have been caused by the increase in medium osmotic pressure rather than direct inhibition by the biochemical (Fig. 9). However, the relative resistance of Campylobacter species to high concentration of MG and the variation in their resistance did differentiate them and might be useful in the development of diagnostic tests or selective media.
CONCLUSION
The employment of the metabolic inhibitors, used in this study, should throw some light at better understanding how these organisms can survive in the environment. Bearing in mind that, in the laboratory, the organism grows only in microaerophilic conditions and yet in the environment such conditions are not easily available. Because different species behaved differently in the presence of different metabolic inhibitors, it is becoming possible to appreciate the metabolic diversity within campylobacters. Some species may have adapted different pathways for the metabolism of certain substrates depending on the conditions they are exposed to. Ultimately, the control of campylobacters, which are widely distributed in the environment and have been responsible for several cases of gastroenteritis in humans, is a necessity.