- Research article
- Open Access
Pleiotropic effects of a rel mutation on stress survival of Rhizobium etli CNPAF512
- Kristien Braeken†1,
- Maarten Fauvart†1,
- Maarten Vercruysse1,
- Serge Beullens1,
- Ivo Lambrichts2 and
- Jan Michiels1Email author
© Braeken et al; licensee BioMed Central Ltd. 2008
Received: 16 June 2008
Accepted: 10 December 2008
Published: 10 December 2008
The rel gene of Rhizobium etli (rel Ret ), the nodulating endosymbiont of the common bean plant, determines the cellular level of the alarmone (p)ppGpp and was previously shown to affect free-living growth and symbiosis. Here, we demonstrate its role in cellular adaptation and survival in response to various stresses.
Growth of the R. etli rel Ret mutant was strongly reduced or abolished in the presence of elevated NaCl levels or at 37°C, compared to the wild type. In addition, depending on the cell density, decreased survival of exponentially growing or stationary phase rel Ret mutant cells was obtained after H2O2, heat or NaCl shock compared to the wild-type strain. Survival of unstressed stationary phase cultures was differentially affected depending on the growth medium used. Colony forming units (CFU) of rel Ret mutant cultures continuously decreased in minimal medium supplemented with succinate, whereas wild-type cultures stabilised at higher CFU levels. Microscopic examination of stationary phase cells indicated that the rel Ret mutant was unable to reach the typical coccoid morphology of the wild type in stationary phase cultures. Assessment of stress resistance of re-isolated bacteroids showed increased sensitivity of the rel Ret mutant to H2O2 and a slightly increased resistance to elevated temperature (45°C) or NaCl shock, compared to wild-type bacteroids.
The rel Ret gene is an important factor in regulating rhizobial physiology, during free-living growth as well as in symbiotic conditions. Additionally, differential responses to several stresses applied to bacteroids and free-living exponential or stationary phase cells point to essential physiological differences between the different states.
Rhizobium etli is a Gram-negative soil bacterium that elicits nitrogen-fixing nodules on its leguminous host plant Phaseolus vulgaris, the common bean plant. Although the precise nutritional conditions under which the bacteroids thrive inside the nodule cells are still not known, the physiological state of the bacteroids needs to adapt to the prevailing conditions such as a microoxic and low pH environment, specific carbon and nitrogenous compounds and the presence of oxidative stress (reviewed by e.g. [1, 2]).
RelA/SpoT homologues are involved in the regulation of the (p)ppGpp level in the cell. Research in Escherichia coli revealed that this molecule is important in the reorganization of the cellular metabolism during nutrient starvation [3–6]. Moreover, the importance of RelA/SpoT homologous proteins and the effector (p)ppGpp during starvation for nutrients or survival in the presence of specific exogenous stresses was demonstrated for a growing number of micro-organisms [5, 7]. In recent years, it has become clear that (p)ppGpp is also required in complex physiological processes such as biofilm formation by Listeria monocytogenes, E. coli and Streptococcus mutans and developmental processes such as multicellular fruiting body formation by Myxococcus xanthus or sporulation by Bacillus subtilis. Also, RelA/SpoT homologous proteins have been reported to be important for the interaction of bacteria, either pathogenic or beneficial, with their eukaryotic host . In symbiotic bacteria, a RelA/SpoT homologue was first characterized in Sinorhizobium meliloti [8, 9]. An S. meliloti rel Sme mutant is unable to induce the stringent response and overproduces succinoglycan, an exopolysaccharide that is important for infection of its host plant Medicago sativa. Moreover, rel Sme is required for nodule formation on its host . It was subsequently demonstrated in R. etli that the inactivation of rel Ret strongly affects symbiosis with its host Phaseolus vulgaris [10, 11]. Plants nodulated by a R. etli rel Ret mutant have a strongly reduced nitrogen fixation activity. Moreover bacteroid morphology is altered in the rel Ret mutant strain. These findings indicate that adjustment of rhizobial physiology may be a key process to establish a successful symbiosis.
Although relA/spoT genes have been described in a large number of bacteria, extensive phenotyping of the corresponding mutants has presently been carried out in only a limited number of species. Because of its putative involvement in stress survival, we performed a detailed examination of the R. etli rel Ret mutant in response to salt, temperature, oxidative and stationary phase stresses. In addition, as the physiological status of rhizobial bacteroids is currently not fully understood, phenotyping of wild-type and rel Ret mutant bacteroids was performed. Our results indicate a prominent role for (p)ppGpp in R. etli survival in the presence of specific stress conditions and in the adaptation of the bacterium to the endosymbiotic bacteroid state.
Growth in the presence of chronic stress
In a previous study, we demonstrated a clear impact of a rel Ret mutation on growth in complex as well as in defined minimal medium . To further explore the role of rel Ret in the presence of various stresses, specific growth experiments were performed.
Survival in the presence of acute stress
In addition to chronic stress growth experiments, survival of wild-type R. etli, rel Ret mutant CMPG8705 and CMPG8705 complemented with pCMPG8715 was determined in the presence of oxidative stress, salt stress, heat shock and cold for cells harvested throughout the growth curve, varying from early logarithmic to late logarithmic-early stationary phase. Cells at different optical densities were challenged with one of the various stresses for a defined time period and the number of surviving CFUs was determined after 3 days of incubation at 30°C.
The effect of heat stress was first determined by shifting the cells to 45°C for 30 min. Wild-type and rel Ret mutant strains showed 2–10% survival depending on the cell density, but did not differ significantly. By contrast, the complemented strain showed survival levels of 50–100% (data not shown). After 60 min incubation, the survival percentages of the rel Ret mutant were 3- to 10-fold lower than those of the wild type (Fig. 3B). The complemented strain displayed increased survival reaching about 1% at OD600 above 0.3. In addition, the effect of prolonged incubation at low temperature was tested. Samples corresponding to a range of OD600 values were incubated without shaking at 4°C. Viability remained essentially unchanged during the first 20 days. At 27 days of incubation, viability dropped (about 10-fold), but no differences were observed between the strains (data not shown).
Finally, given the effects of NaCl on growth, survival after exposure to high concentrations of NaCl was examined. NaCl was added to the cell suspensions to a final concentration of 2.5 M. After 6 h incubation at 30°C, a clear impact on survival was observed (Fig. 3C). The rel Ret mutant showed similar or slightly lower survival compared to the wild type during different repeats of the experiment. Only during late exponential phase, differences are more pronounced (significant at p < 0.05).
Survival of reisolated bacteroids during acute stress
Survival of re-isolated bacteroids following stress application
10 mM H 2 O 2 (30 min) a
10 mM H 2 O 2 (60 min)
45°C (30 min)
45°C (60 min)
2.5 M NaCl (90 min)
2.5 M NaCl (240 min)
Oxidative stress, resulting from the presence of H2O2, hydroxyl and superoxide radicals, is an important stress factor in functioning nodules as reactive oxygen species (ROS) levels are elevated and increase even further during nodule senescence [14, 15]. Therefore, the resistance against oxidative stress was determined for bacteroids isolated at various time points. As can be seen from Table 1, the wild type and complemented strain exhibit close to 100% resistance to a 30 or 60 min treatment with 10 mM H2O2 when isolated from nodules harvested 5 or 6 (data not shown) weeks post inoculation. In contrast, the survival percentage of the rel Ret mutant was only 20–26% (significant at p < 0.05).
Additionally, heat and salt stress were applied to the bacteroids. Surprisingly, resistance to both stresses at 5 weeks post inoculation was consistently found to be slightly higher in the mutant strain (Table 1; significant at p < 0.05). This was also observed 3 weeks post inoculation (data not shown). However, as senescence proceeded, at 6 weeks post inoculation, differences in heat and salt resistance between the studied strains disappeared (data not shown).
Long-term survival in complex and defined medium
In an attempt to determine if the effect on survival was associated with the medium used, the survival profile was also assessed in AMS medium containing 10 mM succinate (Fig. 4B). In contrast to what was observed using TY medium, the wild-type strain survived for a much longer time, reaching about 5 × 105 CFU ml-1 23 days after inoculation. In contrast, the mutant strain displayed a rapid decrease of CFUs from about 5 days after inoculation. The limiting factor in nutrient deprivation in this medium is probably the carbon source, as the concentration of succinate was found to affect final optical densities reached in the stationary phase. In contrast, lowering the ammonium concentration from 10 mM to 2 mM did not affect the growth curve. These data suggest that the rel Ret mutant has stationary phase defects in this carbon-starved medium.
Microscopic analysis of cells in stationary phase
Transmission electron microscopy analysis indicated that the wild type and rel Ret strain exhibited a similar morphology during the exponential phase (OD600 of 0.5; data not shown). At 120 h after inoculation, cells were still intact and the average length of the wild-type bacteria changed from 1.6 μm observed for the exponential phase to 1.2 μm (p < 0.01, student t-test). In contrast, the average length of the rel Ret mutant increased from 1.7 to 2.1 μm although the latter increase was not significant at p < 0.01 (Fig. 5C and 5D). Mutant cells also displayed a more dispersed electron density whereas this seemed much more concentrated at the poles in the wild-type cells. Furthermore, abnormally long cells showing a constriction in the middle were observed for the rel Ret mutant (Fig. 5B and 5E). Strikingly, also during symbiosis, a majority of the rel Ret mutant bacteroids isolated 5 weeks after inoculation were consistently larger but more electron dense compared to the wild type (Fig. 5F and 5G). These data are in agreement with previous results .
Survival of stationary phase cultures during acute stress
Metabolic control and stress resistance
The alarmone (p)ppGpp likely plays a central role in adaptation of the R. etli metabolism as is reflected by the observed growth defects. Given the effect of different carbon sources, there is probably a link between the stringent response and the carbon status of the cell in R. etli. This is further supported by the survival of R. etli CNPAF512 in AMS minimal medium containing 10 mM succinate as the limiting nutrient. Production of (p)ppGpp controlled by carbon metabolism allows the cell to respond to conditions of carbon stress, and as a result would downregulate cellular metabolism. The molecular mechanism connecting the stringent response to the available carbon compounds in bacteria is still a major question to be resolved. Interestingly, differential expression of rel Ret in an R. etli ptsA mutant during symbiosis as well as under free-living aerobic growth was previously observed . In E. coli, the link between the stringent response and the cellular carbon status is exerted through the SpoT protein. Recently, fatty acid metabolism has been shown to control the activity of SpoT .
In a growing number of bacteria, (p)ppGpp is associated with survival of stresses including general (stationary phase) stress as well as more specific ones [3, 4, 17]. In R. etli, mutation of rel Ret also affects heat and NaCl sensitivity, as well as resistance against oxidative stress depending on the growth phase. Moreover, sustained growth in the presence of high temperature and salt concentration was affected as well. Effects on osmotolerance have previously been reported for L. monocytogenes and S. meliloti [18, 19], although the underlying basis is unclear. Here, salt tolerance of R. etli is specifically impaired at the late logarithmic-early stationary phase, so the aberrant cell morphologies observed might be more sensitive to the increased osmotic pressure in the medium. Temperature-sensitive growth has been described for M. tuberculosis rel Mtu , V. cholerae , and also coincides with decreased thermotolerance in E. coli relA mutants . In the latter, this phenotype was osmoremedial. A possible explanation could be the involvement of heat shock proteins. However, overexpresion of σ32 in E. coli did not relieve the observed phenotype. Induction of the heat shock response by (p)ppGpp has been a matter of debate in E. coli. Initially, Grossman et al. (1985)  reported that the stringent response induced heat shock gene expression. In contrast, Van Bogelen and Neidhardt (1990)  found that a relA spoT mutant displayed a modestly altered heat shock response and concluded that (p)ppGpp was neither sufficient nor absolutely necessary. The observation by Yang and Ishiguro (2003)  confirms that expression of heat shock proteins is not sufficient to relieve the temperature sensitivity exhibited by relA mutant strains. However, these authors identified rpoB mutants, previously shown to reverse amino acid auxotrophy, that suppressed the temperature phenotype. This indicates that the effect might be the consequence of a much more general aspect of (p)ppGpp-RNAP interaction. Besides E. coli, research in other bacteria, including Streptococcus pyogenes and M. tuberculosis points to (p)ppGpp-independent induction of heat shock genes [23, 24]. To determine if more general aspects of the (p)ppGpp-mediated gene regulation are involved, it would be worthwhile testing if conserved rpoB suppressor mutations, as also identified in S. meliloti , affect salt sensitivity as well or whether introduction of these mutations in R. etli CNPAF512 reverses both phenotypes, indicating a possible common basis. Finally, alternative σ factors may be implicated in stress resistance in R. etli. The E. coli extracytoplasmic stress factor σE, implicated in the response to cell envelope stress, has recently been shown to be activated by ppGpp .
Stationary phase behaviour
Besides in response to specific stresses, involvement of (p)ppGpp in stationary phase survival has been reported in many organisms. rpoS, whose expression and function is mediated by (p)ppGpp [26, 27], is often important for both specific and general stress resistance. However, R. etli CNPAF512, like ε– and other α-proteobacteria, lacks this stress response factor. Currently, little is known about alternative factors that are involved in these bacteria. Nevertheless, we also observe decreased survival of the rel Ret mutant in AMS succinate and in the early stationary phase in TY medium although cells still appeared intact. This response in TY medium was coupled with aberrant cell morphologies and a rise in the OD600 value, similar to C. jejuni . However, upon a prolonged stationary phase, the colony forming ability of the wild type suddenly dropped in TY medium whereas it remained high in AMS succinate medium for the period studied. Based mainly on research in E. coli, three main models are proposed to account for this loss of reproduction during starvation. The VBNC (viable but non-culturable) – theory states that bacteria initiate a specific pathway generating dormant forms. The other theories suggest that cells become non-culturable due to cellular deterioration or through initiation of programmed cell death pathways, both finally leading to cell death . With respect to cellular deterioration, increased protein oxidation during early stadia of starvation was identified as an important factor in E. coli. This oxidation process was tightly associated with the appearance of aberrant protein forms caused by an increased erroneous incorporation of amino acids . In aerobic conditions, misfolded proteins are oxidized and are in turn responsible for elevated expression of the heat shock protein genes during starvation in E. coli . As bacteria lacking (p)ppGpp fail to adapt their metabolism to starvation conditions, they accumulate misfolded and damaged proteins . This could explain why viability is seriously impaired in the absence of (p)ppGpp as the cellular deterioration process will be enhanced. Accumulation of aberrant proteins might also be reflected in the aberrant cell morphologies observed in TY medium. Furthermore, in a C. jejuni rel Cje mutant nearly all heat shock genes were dramatically upregulated at the onset of the stationary phase when optical density also increases in the mutant . Also, increased sensitivity towards oxidative stress as observed for R. etli rel Ret bacteroids and late stationary phase cultures might correlate with the increased presence of abnormal proteins, which are more susceptible to carbonylation. Another possibility is a relationship between (p)ppGpp and toxin-antitoxin (TA) modules as proposed by work on the mazEF and relBE operons in E. coli. Little information is available about the function of TA loci in rhizobia. Twelve possible TA loci have been identified on the S. meliloti chromosome , with genes homologous to vapBC located immediately downstream of the rel Sme gene. However, analysis of their function might be difficult as there is a high degree of redundancy (e.g. seven possible vapBC loci). In addition, from our sequencing results as well as the recently annotated genome sequence of the R. etli CFN42 chromosome, no evidence could be found for a TA locus downstream of the rel Ret gene.
From our results, it appears that cell morphology in R. etli is also regulated by intracellular levels of (p)ppGpp as the cell size of a rel Ret mutant is increased compared to the wild type once cultures enter the stationary phase as well as in cells differentiated to bacteroids. Similarly, ectopic production of (p)ppGpp in Mycobacterium smegmatis by overexpression of the E. coli relA gene results in a coccoid morphology of the bacteria in contrast to the normal bacilli form and was observed in low nutrient medium and late stationary phase cultures of M. smegmatis as well . Colony and individual cell morphologies also differed between M. smegmatis and the rel Msm mutant, where significantly longer cells were observed with several of the elongated mutant cells containing multiple division septa in the cell . In Helicobacter pylori, deletion of spoT results in premature transformation to a coccoid morphology . Finally, in the ε-proteobacterium C. jejuni, mutation of rel Cje resulted in aberrant cell morphologies observed upon entry in the stationary phase with coccoid, significantly enlarged and electron dense cells. As observed for R. etli, this phenomenon was not reported for bacteria in the exponential phase, indicating that upon entry in the stationary phase, bacteria seem to display a defect in the process of cell division. In addition, the appearance of abnormal cell morphologies in C. jejuni also correlated with a sudden increase in OD600 values and CFU counts revealed a decrease in viability at the initial time points of the stationary phase compared to the wild type in agreement with our observations for R. etli. Although a role for (p)ppGpp in peptidoglycan biosynthesis and septum formation in E. coli was proposed in several studies [36–38], the molecular mechanisms involved are still unclear. In E. coli, it was found that inhibition of cell division by blocking or inactivating penicillin-binding protein 2, which regulates lateral elongation of peptidoglycan, can be relieved by increasing the intracellular concentration of ppGpp [39, 40]. However, a direct effect of ppGpp at the level of transcription of ftsZ, involved in septum formation, was not found . In R. etli, the target(s) of (p)ppGpp involved in the control of cell size are still unknown, however, reduction of the cell size may be an important adaptation of the strain for survival during starvation, in agreement with the observed reduction of cell size during starvation of R. leguminosarum .
TEM microscopic observation of sections of mature nodules of rel Ret mutant strains pointed to aberrant bacteroid morphology in both R. etli CNPAF512 and R. etli CE3 [10, 11]. This was confirmed here for bacteroids isolated 5 weeks after inoculation. In addition, for all time points tested, bacteroid numbers obtained from plants inoculated with the mutant strain were consistently 10-fold lower compared to the wild type. This difference could not be clearly concluded from a previous TEM analysis . Therefore, this difference might be attributed to the failure of a number of bacteroid cells to redifferentiate and form a colony, to a survival defect or to a lower number of bacteroids present in the nodule. Interestingly,  reported that for R. etli CE3 rel Ret , fewer plant cells in the nodule seemed to be invaded. However, a decreased resistance against oxidative stress, as observed here for rel Ret bacteroids, could also influence the number of CFU obtained at different time points during the symbiotic interaction. Oxidative stress, resulting from the presence of H2O2, hydroxyl and superoxide radicals, is an important stress factor in functioning nodules as ROS levels are high . During senescence, the ROS concentration increases even further. For defence against ROS, organisms produce antioxidants and enzymes that prevent or repair oxidative damage. In R. etli, two genes involved in this defence have been described, katG and prxS, encoding a catalase-peroxidase and a peroxiredoxin respectively [43, 14]. These genes partially overlap in function as mutation in both genes is necessary to affect nitrogen fixation . However, prxS, located in an operon with rpoN2, is strongly expressed during the symbiotic interaction, mainly in an RpoN-dependent way. As decreased expression of σN-dependent genes including the rpoN2 gene itself, is observed in rel Ret mutant bacteroids , this could indicate that (p)ppGpp contributes to symbiosis by redirecting gene expression in bacteroids favouring transcription of σN-dependent genes. Besides an overall effect on the physiology, the strongly decreased nitrogen fixation ability and the decreased resistance against oxidative stress of the R. etli rel Ret mutant may result from a decreased expression of specific (symbiotic) target genes including σN-dependent genes such as the rpoN2 gene, prxS and other nitrogen fixation genes. It will be important in future experiments to address the question whether (p)ppGpp may redirect gene expression in bacteroids favouring transcription of σN-dependent genes. Indeed, it was recently shown using an in silico approach for the detection of -24/-12 type of promoters in Rhizobiales that the σN regulon may control more genes than traditionally assumed . Interestingly, S. meliloti class I suppressors carry mutations in a region previously implicated in σ factor recognition .
Upon examination of stress resistance, bacteroids, isolated either at 35 or 42 days post inoculation, differ considerably from free-living bacteria. In general, in the presence of temperature, salt or oxidative stress, wild type bacteroids display a higher resistance compared to exponentially growing or stationary phase cells. Also, the response of the rel Ret mutant against these stresses differs. Overall, while exponentially growing or stationary phase rel Ret - cells display increased sensitivity to heat, salt or H2O2 compared to the wild type, this is not the case in bacteroids. These results indicate that bacteroid physiology is profoundly different from free-living cells.
Here, the central role of the previously identified rel Ret gene region in cellular metabolism and stress resistance was further investigated. We demonstrate stress-dependent phenotypic differences between the wild type and rel Ret mutant. Furthermore our observations point to clear differences between the physiological status of free-living and symbiotic bacteria in relation to stress resistance. Taken together, our data demonstrate that (p)ppGpp-mediated regulation is important for physiological adaptation of free-living bacteria subjected to metabolic or stationary phase stresses and of R. etli bacteroids to the conditions prevailing in the nodules.
Bacterial strains and culture conditions
Bacterial strains and plasmids
Strain or Plasmid
Source or reference
Michiels et al., 1998a
Spr, rel Ret :: Ω-Sp, opposite orientation
Apr Tcr, stable RK2-derived cloning vector
Dombrecht et al., 2001
rel Ret gene in pFAJ1702
Plant experiment and bacteroid isolation
Seeds of Phaseolus vulgaris cv. Limburgse vroege were sterilized and germinated as previously described . Plants were inoculated with 100 μl of an overnight bacterial culture resuspended at an OD600 of 0.4 in 10 mM MgSO4 . For each R. etli strain at least 10 plants were inoculated. Snoeck medium was used to grow the common bean plants . Plants were grown in a plant growth room with a 12 h photoperiod (day/night temperature 26°C/22°C; relative humidity 65–70%). Nitrogenase activity was determined by measuring acetylene reduction activity of nodulated roots in a closed vessel three weeks after inoculation. Samples were analyzed by a Hewlett-Packard 5890A gas chromatograph equipped with a 'PLOT fused silica' column and an HP3396A integrator. Propane was used as an internal standard. For stress experiments, bacteroids were purified from the nodules by differential centrifugation  and subsequently resuspended in 10 mM MgSO4.
Growth experiments and bacterial survival during stress
To study bacterial growth over an extended period of time, overnight cultures of the strains were washed and diluted to an optical density (at 600 nm) of 0.5 in 10 mM MgSO4. Subsequently, these cultures were diluted 100-fold in 10 mM MgSO4 after which 295 μl of the growth medium (TY or AMS medium supplemented with carbon and nitrogen sources at 10 mM concentrations) was inoculated with 5 μl of the suspension (dilution approximately 6000-fold). Optionally, medium was supplemented with NaCl as indicated in the text. To study temperature sensitivity, growth was monitored at 37°C. The optical density was measured automatically at 600 nm every 30 min in a Bioscreen C (Labsystems Oy) during at least 4 days. For each time point, the average optical density was calculated from 5 independent measurements. Experiments were repeated at least twice.
To study stress survival, an overnight culture was used to inoculate 5 ml TY cultures with a dilution factor ranging from 1/10 to 1/10,000. After overnight incubation, the optical density of these TY cultures at 600 nm was determined and for a range of optical densities between 0.1 and 1, appropriate cultures were selected. Subsequently, a volume of 0.5 ml of the selected samples was placed in a 30°C water bath for one hour in the presence of 10 mM H2O2, in a 30°C incubator (shaking at 200 rpm) for 1.5 h and 6 h in the presence of 2.5 M NaCl, or in a water bath at 45°C. Samples were removed at the indicated time points, dilution series were prepared in 10 mM MgSO4 and plated on TY plates containing nalidixic acid. Control samples were incubated without the stress agent at 30°C and the control CFU numbers were determined at the 0 h timepoint as well as at the same timepoint as the stressed samples. Colonies were scored after three days incubation at 30°C. The total number of colony forming units (CFU) per ml culture was calculated. Experiments were repeated at least three times.
To study survival, wild-type and mutant strains were precultured in TY medium. Subsequently, cell pellets were washed and resuspended in the indicated medium at an optical density at 600 nm of 0.4. A volume of 100 ml culture medium was then inoculated with 1 ml of this suspension and incubated at 30°C. Samples of 1 ml were removed at the indicated time points and 10-fold dilution series were prepared and plated on TY or AMS succinate plates or on the same plates containing 30 μg ml-1 nalidixic acid. Colonies were scored after three days incubation at 30°C. For a number of time points, heat (45°C) sensitivity, oxidative stress (10 mM H2O2) and NaCl sensitivity (2.5 M) were tested as described above.
For bacteroid experiments, three samples were tested for each strain. To prepare a sample, nodules from 3 different inoculated plants were isolated, weight was determined and bacteroids were isolated  and suspended in 4.5 ml 10 mM MgSO4 (approximately equal numbers). Stress survival of bacteroids in the presence of 10 mM H2O2 or 2.5 M NaCl or at 45°C was determined as described for free-living bacteria. Finally, bacteroids were diluted in MgSO4 before plating. Values were calculated as CFU per gram nodule.
Light microscopic examination of bacteria was done on a Nikon Optiphot-2 microscope equipped with a fluorescence unit after staining of the bacteria (diluted in 10 mM MgSO4), with the LIVE/DEAD BacLight Bacterial Viability kit (Molecular Probes). 1 μl of each staining solution (SYTO 9 and propidium iodide) was added to 600 μl of the cell suspension and incubated for 15 min in the dark. Samples were placed on poly-lysine coated glass plates or concentrated by filtration on a 0.1 μm filter (Millipore). Images were taken using a digital DS camera head DS-5M (Nikon) controlled by a DS Camera Control Unit DS-L1.
For transmission electron microscopy (TEM) analysis, bacterial cells were adsorbed to uncoated grids. The grids were placed on a drop of bacterial suspension for 15 seconds, then incubated in 0.25% phosphotungstenic acid (pH 7) for 30 seconds, washed several times and excess liquid was drained. The bacteria were observed with a Philips EM 208S transmission electron microscope at 80 kV. Images were digitized using the SISR image analysis system.
KB is indebted to the Research Fund K.U.Leuven for financial support (PDM/06/196). This work was supported by grants from the Research Council of the K.U.Leuven (GOA/2003/09) and from the Fund for Scientific Research-Flanders (G.0108.01 and G.0287.04).
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