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Applied and Environmental Microbiology, September 1999, p. 4181-4188, Vol. 65, No. 9
0099-2240/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Bacterial Growth State Distinguished by Single-Cell
Protein Profiling: Does Chlorination Kill Coliforms in Municipal
Effluent?
David
Rockabrand,
Teresa
Austin,
Robyn
Kaiser, and
Paul
Blum*
School of Biological Sciences, University of
Nebraska, Lincoln, Nebraska
Received 15 September 1998/Accepted 9 June 1999
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ABSTRACT |
Municipal effluent is the largest reservoir of human enteric
bacteria. Its public health significance, however, depends upon the
physiological status of the wastewater bacterial community. A novel
immunofluorescence assay was developed and used to examine the
bacterial growth state during wastewater disinfection. Quantitative levels of three highly conserved cytosolic proteins (DnaK, Dps, and
Fis) were determined by using enterobacterium-specific antibody fluorochrome-coupled probes. Enterobacterial Fis homologs were abundant
in growing cells and nearly undetectable in stationary-phase cells. In
contrast, enterobacterial Dps homologs were abundant in
stationary-phase cells but virtually undetectable in growing cells. The
range of variation in the abundance of both proteins was at least
100-fold as determined by Western blotting and immunofluorescence analysis. Enterobacterial DnaK homologs were nearly invariant with
growth state, enabling their use as permeabilization controls. The
cellular growth states of individual enterobacteria in wastewater samples were determined by measurement of Fis, Dps, and DnaK abundance (protein profiling). Intermediate levels of Fis and Dps were evident and occurred in response to physiological transitions. The results indicate that chlorination failed to kill coliforms but rather elicited
nutrient starvation and a reversible nonculturable state. These studies
suggest that the current standard procedures for wastewater analysis
which rely on detection of culturable cells likely underestimate fecal
coliform content.
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INTRODUCTION |
Rivers and lakes beside most U.S.
municipalities are categorized as recreational sites and are primary
locations for municipal effluent discharge. Escherichia coli
is monitored in such water as an indicator species for human fecal
contamination and consequently is the primary measure of public health
risk for communicable disease (5, 38). The Environmental
Protection Agency requires that discharged municipal effluent contain
no more than 4,000 fecal coliforms per liter (18). To meet
these requirements, fecal coliform content usually is adjusted by
chlorination with chlorine gas or chloramines, followed by residual
chlorine neutralization with sulfur dioxide (53).
Since wastewater comprises a diverse community of microbial taxa,
standard procedures for fecal coliform enumeration rely on selective
enrichment techniques using detergent additives (18). However, studies on coliform regrowth in chlorinated drinking water
indicate that such techniques significantly underestimate coliform
death due to chlorine injury that induces a viable-but-nonculturable (VNC) state (14, 32, 33). Because resuscitation of injured cells can occur, it is well recognized that most standard procedures may underestimate the incidence of the indicator species and therefore distort water quality estimates (16, 43, 56). Established procedures for drinking water analysis have since been amended to
address this concern (18).
Many factors which limit bacterial proliferation can precipitate the
VNC state (36, 41). Reversible loss of culturability has
been characterized in great detail in vibrios (44, 54) and
is of particular importance in estimating the occurrence of cholera, a
waterborne disease (15). In natural samples, the disparity
between total and culturable cell counts and the diversity of 16S rRNA
sequences apparent in uncultivated samples compared to culture
collections indicate that most bacteria are unculturable (2, 7,
50). This suggests that the VNC state is widespread. Despite
efforts to clarify the physiological basis for this state, the
relationship between true metabolic dormancy and the VNC state remains
unclear. In contrast, much has been learned about the early stationary
phase (10, 22, 23) which precedes both the VNC state and
metabolic dormancy. We suspected that similar issues might apply to
coliforms in wastewater effluent after chlorination. To evaluate the
VNC state, we developed a novel single-cell method to determine
physiological status based on profiling of growth state-specific proteins.
To understand the physiological basis for chlorination-induced loss of
culturability in wastewater coliforms, three cytosolic proteins were
selected as targets for in situ analysis of uncultivated cells. This
new method is called protein profiling and was used to differentiate
growing (exponential-phase) from nongrowing or stationary-phase cells.
DnaK (HSP70), a molecular chaperone (20, 31), plays a
critical role in both exponential- and stationary-phase physiology
(13, 45, 49). DnaK is a metabolically stable protein whose
abundance changes only moderately in response to nutrient deprivation
(47), permitting its use as a permeabilization control. Dps
is a highly conserved 19-kDa DNA binding protein (1, 30)
important in stationary-phase stress physiology (1, 30, 47).
Dps abundance is inversely correlated with growth rate, and it varies
in cellular concentration over 100-fold between the extremes of
stationary phase and rapid growth (1, 30, 40, 47). Dps
abundance was used as a positive indicator of nongrowth (e.g.,
starvation or stationary phase). Fis is an 11-kDa DNA binding protein
(25, 26) which plays a critical role in coordinating rRNA
synthesis with growth (39). Fis is therefore present in
replicating cells, and its abundance is directly correlated with the
growth rate (4, 52). Fis abundance varies over 500-fold between the extremes of rapid growth and stationary phase. Fis abundance was used as a positive indicator of growth. Results presented
here include the development of the protein profiling method using
wild-type and mutant populations of E. coli and its utility
for studies on the major enteric bacterial genera. The protein
profiling method was then used to study the physiological status of
coliform bacteria in raw and chlorinated wastewater.
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MATERIALS AND METHODS |
Bacterial strains, plasmids, and cultivation.
The E. coli K-12 strains used were PBL500
(lacZ::Tn5 lacIq1) and
PBL501 (
dnaK52::Cmr
lacZ::Tn5 lacIq1) as
described previously (45); PBL755
(fis::Tn10) and PBL664 (dps) were constructed as indicated later in this report,
and DH5
[
80dlacZM15 (lacZYA-argF)
U169 deoR recA1 endA1 hsdR17 (rK
mK+) supE44 thi-1 gyrA69] was
obtained from Gibco-BRL. Cell densities in both growing and starving
cultures were monitored spectrophotometrically at a wavelength of 600 nm. The media used were LB (34), m-T7 (Difco), m-Endo (BBL),
Lauryl Tryptose broth (Difco), and EC broth (BBL). The medium used for
Tets selections was prepared as described previously
(11). Ampicillin and tetracycline were added at final
concentrations of 100 and 12 µg/ml, respectively. Tests for chlorine
injury of wastewater organisms were performed by spread plating of
wastewater effluent dilutions with and without chlorination onto m-T7
or m-Endo agar plates in duplicate. Less than 1% variation was
observed between replicate samples. Most probable numbers (MPNs) were
determined as described previously (18). The bacterial
community in raw wastewater samples was allowed to exhaust endogenous
nutrients by continued incubation at ambient temperatures with gentle
shaking in flasks until total cell numbers were observed to undergo no further increase.
Strain constructions.
Molecular biology methods were
performed as described previously (8, 46). Analysis of DNA
sequences was done as previously described (42). The
fis mutant was constructed by phage M13-mediated recombination (9). A 2.1-kb HindIII fragment
spanning fis from phage 
-529 (27) was ligated
into the HindIII site of pACYC177 (New England Biolabs).
The tet gene from pBR322 (Gibco-BRL) was subcloned as a
1.4-kb EcoRI-StyI fragment into pUC19 (New
England Biolabs) at the EcoRI-XbaI sites and then
subcloned again as a 1.7-kb PvuII fragment into the
HpaI site at nucleotide 48 of fis. The region
spanning the disrupted fis gene was subcloned as a 3.5-kb
AgeI-NsiI fragment into the
XmnI-PstI sites of M13mp9 (9). An
additional 150 bp from the middle of the fis gene were
deleted by BstEII digestion.
M13mp9::fis::tet was then
transformed into DH5 F' Kanr (Gibco-BRL), and the
resulting lysate was used to produce strain PB755 by homologous
recombination. The dps mutant was constructed by transducing
strain PBL500 with phage P1 (184593)
(zbi-29::Tn10) (48), and
Tets derivatives were recovered as previously described
(11). Imprecise Tn10 excision deleted
dps, as indicated by Western blot analysis and generation of
chlorate resistance (24).
Source and treatment of wastewater samples.
Wastewater
samples were obtained from a municipal treatment plant serving a
population of 200,000. The wastewater in this facility is treated via
an activated-sludge process, followed by disinfection by injection of
chlorine gas, which is neutralized with sulfur dioxide gas before
release. The initial chlorine concentration in the contact basin is 3.5 mg/liter and has a contact time of 1 h. Raw wastewater samples
used in this study were taken from the effluent of the final or
secondary clarifiers prior to chlorination. Chlorinated samples were
collected from the effluent from the chlorine contact basin. One-liter
volumes of secondary treated wastewater were shaken at 200 rpm at
25°C on a G-33 shaker (New Brunswick). Sodium hypochlorite was added
to achieve 3.5 or 7 mg of available chlorine per liter, as indicated in
Results. After 1 h, sodium thiosulfate was added (15 mg/liter) to
neutralize the remaining free chlorine (18). Nutrient
resupplementation was accomplished by addition of tryptone (0.1%,
wt/vol) following neutralization.
Cloning, purification, and antibody production for Fis.
The
fis gene was amplified by PCR using
5'-TTGAATTCATGTTCGAACAACGCG-3' (forward primer) and
5'-TTCTTAAGAGCATTTAGCTAACC-3' (reverse primer) from PBL500.
The resulting PCR product was cloned into pUC19 following
EcoRI digestion, placing fis under
Plac control. A DH5 (Gibco-BRL) transformant was used
for Fis purification as previously described (37). Boiling
of cell lysates, followed by clarification by centrifugation at
200,000 × g for 3 h at 4°C, was used prior to
ammonium sulfate precipation to facilitate protein removal. The
resulting dialyzed material was fractionated by DNA cellulose
chromatography as previously described for Dps (1) and
purified to homogeneity by electroelution following sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE).
Antibodies and synthesis of probes.
Preparation of
antibodies was done as described previously (8, 28). Rabbit
sera containing anti-DnaK, anti-Dps, and anti-Fis antibodies were
processed with acetone powders from homologous mutant strains and then
fractionated by immunoaffinity chromatography. The antibodies were
further purified by affinity chromatography with protein A-Sepharose as
described previously (28). Anti-DnaK antibodies were coupled
to 7-amino-4-methylcoumarin-3-acetic acid (AMCA X), anti-Dps antibodies
were coupled to fluorescein isothiocyanate (FITC), and anti-Fis
antibodies were coupled to Texas Red X in accordance with the
manufacturer's (Molecular Probes) protocols. The 16S rRNA probe
specific for Enterobacteriaceae described previously (35), with the sequence
5'-CATGAATCACAAAGTGGTAAGCGCC-3', was purchased prelabeled
with fluorescein by the manufacturer (Gibco-BRL).
Microscopy sample preparation and probing procedures.
Cells
were fixed by resuspension in phosphate-buffered saline, addition of
4% (wt/vol) paraformaldehyde, and incubation at 4°C for 3 h
with mixing. Washed cells were resuspended in equal parts
phosphate-buffered saline and ethanol. Gelatin-subbed slides were
prepared by dipping clean slides into a solution of 0.1% (wt/vol)
gelatin and 0.01% (wt/vol) CrK(SO4)2 in
deionized water and then air drying them at room temperature for 10 min. Fixed cells were applied to treated slides and dried at 37°C and
dehydrated by successive rinses in 50, 80, and 98% ethanol. Cell
permeabilization was accomplished by lysozyme-EDTA treatment
(57) with lysozyme (5 mg/ml) in 100 mM Tris-HCl-50 mM EDTA
(pH 8.0). Rinsed, dried slides were then simultaneously treated with
all three probes in the dark and suspended in 2% (wt/vol) bovine serum
albumin-150 mM NaCl-100 mM Tris-HCl (pH 7.5) for 1 h in a
humidified chamber. Slides were washed in 150 mM NaCl-100 mM Tris-HCl
(pH 7.5)-1% Triton X-100-1% deoxycholic acid-0.1% SDS for 10 min,
rinsed in water, and dried at 37°C. Fluorochrome bleaching was
minimized by phenylenediamine treatment (55) prior to
application and sealing of the coverslip. Single-cell 16S rRNA analysis
using the fluorescein-labeled oligodeoxynucleotide was done as
previously described (21). Simultaneous use of antibody and
nucleic acid probes employed the standard antibody probe procedure at
42°C. Specificity of the 16S rRNA probe was maintained in the absence of formamide. Fluorescence microscopy of raw and treated wastewater bacterial communities was performed in replicate by using samples obtained on different days from the wastewater processing facility. Variation in Fis and Dps cellular abundance observed during
reconstruction experiments using raw wastewater followed similar trends
despite the use of samples obtained on different days.
Micrograph analysis.
Fluorescence emission from the
fluor-labeled antibody probes was detected by using a Microphot
epifluorescence microscope (Nikon), an LEI-750 charge-coupled device
camera (Leica), and Omega XF22, XF03, and XF43 filter sets for
fluorescein, AMCA X, and Texas Red X, respectively. Images were
captured, cells were counted, and fluorescence was quantitated by using
Image-1 image analysis software (Universal Imaging). Fis, Dps, and DnaK
levels were determined by measuring the fluorescence intensity of the corresponding fluorochrome-labeled antibodies (FITC, Texas Red X, and
AMCA X, respectively) for each of 1,000 cells per time point. Variation
in individual cell permeability was minimized by normalizing Fis and
Dps fluorescence to that for DnaK on a per-cell basis. Percentage of
maximum cellular fluorescence was determined by assigning a value of
100% to the highest level of fluorescence of the normalized Fis-FITC
label and the normalized Dps-Texas Red X label. All remaining values
were divided by that value and multiplied by 100 to calculate the
percentage of maximum cellular fluorescence.
SDS-PAGE and Western blotting.
Prior to electrophoresis,
samples were adjusted to 250 mM Tris-HCl (pH 6.8)-2% SDS-0.75 M
2-mercaptoethanol-10% glycerol-20 µg of bromophenyl blue per ml
and boiled for 10 min. Proteins were resolved by SDS-PAGE with 4%
(wt/vol) acrylamide stacking and 16% (wt/vol) acrylamide separating
gels as described previously (45, 47), with prestained
molecular mass markers (Novex). Western blots were prepared essentially
as described previously (47). Western blots were probed with
a 1:1,000 dilution of the rabbit sera and then a 1:1,000 dilution of
sheep anti-rabbit horseradish peroxidase conjugate (Gibco-BRL). Western
blots were processed and developed with the ECL reagent system in
accordance with the manufacturer's (Amersham) protocol.
Chemiluminescence was detected by exposing Kodak XAR film. Protein
abundance was determined by comparison to purified standards as
previously described (47).
Phylogenetic analysis.
Phylogenetic analysis (distance) of
16S rRNA sequences from selected proteobacteria was performed with
PHYLIP 3.57c (19) to examine the generality of the 16S rRNA
probe specific for Enterobacteriaceae (35). A
906-nucleotide region spanning positions 496 to 1502 of the E. coli rRNA gene was used to prepare a sequence alignment. The
following sequences were used to construct the tree: CCRRRNAC (Caulobacter crescentus), BSUB16SR (Bacillus
subtilis), D88008 (Alcaligenes faecalis), X06684
(Pseudomonas aeruginosa), AC16SRD (Acinetobacter
calcoaceticus), EA16SRR (Erwinia amylovora), M59160 (Serratia marcescens), HAFRR16SA (Hafnia alvei),
YEN16SA (Yersinia enterocolitica), RAATCR (Rahnella
aquatilis), X07652 (Proteus vulgaris), D78009
(Xenorhabdus nematophilus), KCRRNA16S (Kluyvera cryocrescens), M59291 (Citrobacter freundii), AB004750
(Enterobacter aerogenes), U33121 (Klebsiella
pneumoniae), AB004754 (Klebsiella oxytoca), ST16SRD
(Salmonella typhimurium), SF16SRD (Shigella flexneri), and I10328 (E. coli). A multiple-sequence
alignment was made with CLUSTAL W (51). SEQBOOT was used to
generate 100 bootstrapped data sets. Distance matrices were calculated
with DNADIST using the default options. One hundred unrooted trees were
inferred by neighbor-joining analysis of the distance matrix data by
using NEIGHBOR. Bias introduced by the order of sequence addition was
minimized by randomizing the input order. The most frequent branching
order was determined with CONSENSE.
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RESULTS |
Chlorine injury of coliforms in wastewater.
The occurrence of
chlorine injury of coliforms in chlorinated wastewater was determined
as previously described for drinking water (14, 32, 33).
Municipal wastewater chlorination reduced the number of CFU on
selective medium (m-Endo) by nearly 100-fold relative to an untreated
sample (4.92 × 103 versus 5.02 × 105 CFU/ml). In contrast, no reduction in plating
efficiency was observed when a medium (m-T7) designed to recover
chlorine-injured coliforms (5.30 × 105 CFU/ml) was
used. Similar results were obtained with wastewater samples obtained on
different days. These results indicate that the loss of culturability
observed when selective growth conditions are used results from the
induction of a nonculturable state by chlorination.
Protein profiling for single-cell physiological status.
Target
protein abundance in E. coli populations during growth and
starvation initially was determined by Western blot analysis using
DnaK, Fis, and Dps antibodies (Fig. 1A to
C, lanes 1 and 2). Antibody specificity was verified by the absence of
cross-reacting material in extracts of mutants lacking the structural
genes for the target proteins (Fig. 1A to C, lanes 3 and 4).
Single-cell protein profiles then were determined by simultaneously
probing a mixed population of growing and starving wild-type E. coli bacteria with all three antibodies individually coupled to
distinct fluorochromes. Examination of individual fields at each of
three wavelengths revealed the identities of growing and starving cells
(Fig. 1D to F). All cells could be observed by using the DnaK probe
(Fig. 1D). Starving cells only had high levels of Dps (Fig. 1E), while growing cells only had high levels of Fis (Fig. 1F).
Fluorescent-antibody probe specificity was confirmed by using mixed
populations of wild-type and mutant E. coli strains for each
of the target proteins (Fig. 1G to L).
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FIG. 1.
Growth state and target protein specificity of antibody
probes. Western blots of various cell extracts of growing (exponential
phase [Expo.]) and starving (stationary phase [Stat.]) wild-type
(lanes 1 and 2) and mutant (lanes 3 and 4) E. coli strains
were visualized by chemiluminescence (A to C). Molecular mass standards
(kilodaltons) are indicated at the left of each panel. Single-exposure
fluorescence micrographs show growing and starving wild-type E. coli cells mixed at a 1:1 ratio, probed with the three
fluorochrome-labeled antibody probes, and visualized by using
fluor-specific filters. Shown are AMCA X-labeled anti-DnaK (D), Texas
Red X-labeled anti-Dps (E), and FITC-labeled anti-Fis (F) antibodies.
Bright-field and single-exposure fluorescence micrographs show
wild-type and mutant E. coli cells mixed at a 1:5 ratio and
probed with AMCA X-labeled anti-DnaK antibody (G and H), Texas Red
X-labeled anti-Dps antibody (I and J), and FITC-labeled anti-Fis
antibody (K and L). The left panel in each set (G to L) is a
phase-contrast bright-field image of the same field viewed by
fluorescence in the right panel.
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Phylogenetic specificity of the protein profiling method.
Wastewater bacterial communities are comprised of many taxa, although
Enterobacteriaceae or coliforms are of primary importance (29). It was therefore necessary to evaluate the
phylogenetic specificity of the antibody probes to discriminate between
the percentage of coliform species detectable in wastewater samples relative to the detection frequency of noncoliform species. Western blot analysis of pure cultures of selected species indicated that all
major enterobacterial genera contained the target proteins and that
their synthesis was regulated as observed in E. coli (Fig.
2A and data not shown). P. aeruginosa, a common wastewater inhabitant (3), was
used as a noncoliform control. A DnaK homolog was detected in this
organism (Fig. 2A) (28), but Dps and Fis were not evident.
These results indicated that the method effectively detected coliforms.
To preclude enumeration of noncoliform species, only DnaK-containing
cells which exhibited detectable levels of either Dps or Fis were
scored in subsequent studies.
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FIG. 2.
Phylogenetic range of antibody probes. Western blots of
cell extracts of growing (E) and starving (S) wild-type
Enterobacteriaceae and a member of the gamma subdivision of
the subclass Proteobacteria probed with anti-Fis, anti-Dps,
or anti-DnaK antibodies were visualized by chemiluminescence (A).
Single-cell detection was done by using an FITC-labeled 16S rRNA probe
specific for Enterobacteriaceae (+,  ). Bright-field (B1)
and single-exposure fluorescence (B2 and B3) micrographs of the same
field of cells from raw wastewater probed simultaneously with AMCA
X-labeled anti-DnaK antibody (B2) and an FITC-labeled 16S rRNA probe
(B3) are shown. Representative cells nonfluorescent with either probe
are indicated by arrows. Abbreviations for species used: E. c., E. coli; K. p., K. pneumoniae; E. a., E. aerogenes; C. f., C. freundii; P. v., P. vulgaris; S. m., S. marcescens; P. a., P. aeruginosa.
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A 16S rRNA probe specific for
Enterobacteriaceae
(
35) was employed to further test the specificity of the
antibody probes
by using pure cultures (Fig.
2A). The utility of the
16S rRNA
probe for detection of a more comprehensive set of
Enterobacteriaceae than described previously (
35)
was first verified by phylogenetic
analysis and indicated that the
probe sequence was complementary
to all of the 16S rRNA sequences of
the major genera of
Enterobacteriaceae.
Raw wastewater
samples analyzed by simultaneous probing with the
AMCA X-coupled DnaK
antibody and fluorescein-coupled 16S rRNA
oligonucleotide exhibited
nearly complete (99.75%) overlap of
cells detected by the two probes
(Fig.
2B). These results indicate
that noncoliform taxa did not
interfere with coliform detection
in these studies. These results also
demonstrate compatibility
between nucleic acid hybridization for taxon
identification and
protein profiling for physiological
analysis.
Protein profiling of uncultivated bacteria.
The protein
profiling procedure was then applied to studies of uncultivated
coliforms in chlorinated and raw wastewater. Raw, untreated samples
were analyzed by using the fluor-labeled antibody probes applied
simultaneously. These samples were found to consist primarily of
Fis-containing cells which were nearly devoid of Dps (Fig.
3A). Only a few cells in such samples
contained detectable levels of Dps (Fig. 3A, arrow). The images shown
in Fig. 3A to C are composites of FITC and Texas Red X emission. There
was good concordance in this sample between cells found to contain Fis and those containing DnaK (data not shown). In contrast, chlorinated samples consisted primarily of Dps-containing cells with nearly undetectable levels of Fis (Fig. 3B). Again, all Dps-containing cells
also contained DnaK (data not shown). Surprisingly, cells from raw
water samples which had been allowed to enter stationary phase by
continued incubation at ambient temperatures also exhibited the
high-Dps and low-Fis protein profile (Fig. 3C). Because of the
similarity between chlorinated samples and untreated samples which had
been allowed to enter stationary phase, it was unclear whether this
protein profile was the result of oxidation or starvation. To
understand which stimulus was responsible, wastewater chlorination was
tested for its effects on the growth of newly inoculated cells. A raw
wastewater sample and a chlorinated (neutralized) derivative sample
were sterilized by filtration and inoculated with growing wild-type
E. coli. No growth was observed in the treated water after 3 days of incubation. In the untreated water, however, growth (g = 3 h) and a high cell yield (5.26 × 108 CFU/ml) was
observed. This indicates that there were insufficient nutrients to
support bacterial growth and therefore that the preponderance of
Dps-containing cells in chlorinated wastewater results from conditions
of starvation.
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FIG. 3.
Growth state of coliform bacteria in chlorinated and raw
wastewater. Fluorescence micrographs show wastewater samples probed
with the three fluor-labeled antibody probes. Panels: A, raw sample; C,
raw stationary-phase sample; B, chlorinated sample. Double exposures
are shown which combine images of FITC (anti-Fis)- and Texas Red X
(anti-Dps)-probed samples. Quantitation of numbers of cells with
detectable Dps or Fis as percentages of the total number of cells
examined is shown in panel D. Bars: green, Fis-containing cells; red,
Dps-containing cells. Error bars indicate the variation observed for
each cell type observed among three fields of view; approximately 400 cells were examined for each condition. The arrow in panel A indicates
the location of a rare Dps-containing cell in untreated wastewater.
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Resuscitation of coliforms in treated wastewater.
To test the
possibility that chlorinated wastewater might be nutrient deficient,
raw wastewater samples were chlorinated and then supplemented with
nutrients (Fig. 4). Standard chlorination (3.5 mg/liter, 1 h) resulted in an initial 1,000-fold reduction in
coliform content as determined by MPN analysis. Without nutrient supplementation, no subsequent change in MPNs was observed despite prolonged incubation at ambient temperatures (Fig. 4, inverted triangles). However, in supplemented cultures, culturability reached pretreatment levels within a 9-h incubation period (Fig. 4, circles). If the increase in culturable fecal coliforms observed after standard chlorine treatment resulted from the growth of a small surviving subpopulation, it would necessitate that such cells divide with a
54-min doubling time at 24°C and initiate division without a lag.
Since the measured growth rate of endogenous cells in raw water samples
was 150 min, rapid regrowth of a subpopulation appears improbable.
Instead, the supplementation-induced increase in MPNs more likely
results from resuscitation of dormant cells. The rate of increase in
MPNs in supplemented cultures was inversely proportional to the degree
of chlorination; a doubling of the chlorine concentration from 3.5 to
7.0 mg/liter greatly reduced the rate of increase in the appearance of
culturable cells (Fig. 4, squares). In this latter case, the rate of
increase in MPNs was consistent with the regrowth of a subpopulation of
surviving cells.
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FIG. 4.
Coliform regrowth and protein profiling in chlorinated
wastewater. MPNs (open symbols) and DnaK-containing total fluorescent
cell counts (closed symbols) of chlorine-treated (3.5 [ ,  ,  ,
 ] or 7 [ ,  ] mg/liter) wastewater samples with nutrient
supplementation (0.1% [wt/vol] tryptone; , , , ) and
without additions (, ) are shown. MPNs were determined by using
EC broth. Total fluorescent (DnaK-containing)-cell counts were
determined by using samples with and without nutrient
supplementation.
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Single-cell protein profiling distinguishes resuscitation from
regrowth.
The inability to distinguish between resuscitation of
viable but otherwise nonculturable cells rather than regrowth of
surviving subpopulations lies at the heart of much recent controversy
concerning the VNC state (6, 12, 17). To resolve this issue
in the present case, the fluor-labeled antibody probes were used to
quantify the growth state of individual cells by protein profiling in
response to chlorination and nutrient supplementation. A raw wastewater sample was chlorinated for 1 h, neutralized, and monitored for an
additional 8 h. The quantities of Fis (green) and Dps (red) in
1,000 cells were then examined at selected time intervals. The results
obtained at the beginning of the experiment and 60 min following
chlorination are shown in Fig. 5. The
results obtained for the entire experiment are presented in Fig.
6A. Fis and Dps cellular abundances were
determined by normalizing protein-specific fluorescence intensity on an
individual-cell basis to the amount of DnaK detected in the same cell.
This minimized the variation resulting from differential cell
permeability to the antibody probes. These values are presented as
percentages of the maximum cellular fluorescence observed for all
cells. Numbers of cells with specific Fis and Dps contents were then
summed into groups comprising 5% incremental amounts of either
protein, and the relative abundance of cells in these groups is shown
as a percentage of the total number of fluorescent cells. Upon chlorine
addition (Fig. 5 and 6A), there was a rapid reduction in the number of cells containing Fis and the quantity of Fis in these cells. These changes were largely complete within the treatment time (1 h) and prior
to chlorine neutralization. A concomitant increase in the number of
Dps-containing cells and the quantity of Dps per cell was also
observed. During this period, there was no change in the total number
of fluorescent cells (Fig. 4, closed symbols), thus eliminating lysis
as a contributing factor.
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FIG. 5.
Quantitative analysis of cellular Fis and Dps contents
and abundances of cell types following treatment of raw wastewater by
chlorination. Samples were examined immediately before (A) or 60 min
after (B) treatment. Cellular contents of Fis (green balls and lines,
upper panel) and Dps (red balls and lines, lower panel) are indicated
as percentages of the maximum cellular fluorescence of the brightest
cell in each sample (y axis). Lines extending from above to
below the midpoint line indicate Fis and Dps contents, respectively, of
the same individuals. The abundances of cells exhibiting particular
degrees of fluorescence are shown as percentages of fluorescent cell
type (x axis). Ball size is proportional to the abundance of
that fluorescent cell group using four sizes: large, 100 to 50%;
medium, 50 to 10%; small, 10 to 3%; smallest, 3% to undetectable.
Cells are grouped into clusters based on 5% increments of individual
cellular fluorescence.
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FIG. 6.
Quantitative analysis of single-cell Fis and Dps
contents and abundance of cell types. Samples were chlorine treated (A
and B, 3.5 mg of chlorine per liter; C, 7 mg/liter) and either not
resupplemented with nutrients (A) or nutrient resupplemented (B and C).
The data are presented as indicated in the legend to Fig. 5 with the
added dimension of experimental time (z axis) and 90°
rotation of the figure relative to the previous figure. Changes in Fis
and Dps protein profiles indicating resuscitation (A and B, ovals) and
subpopulation regrowth (A and C, circles) are indicated. Similar trends
in the cellular concentrations of Fis and Dps were observed in
replicate trials. One thousand cells were examined for each sample time
point.
|
|
The response of individual cells to nutrient supplementation following
chlorine treatment (3.5 mg/liter) and neutralization
was also examined
(Fig.
6B). The initial response to chlorination
was as observed
previously (Fig.
6A). However, 2 h after nutrient
addition, an
increasing fraction of fluorescent cells changed
their protein profile
(Fig.
6A and B, ovals). Dps-containing cells
and the quantity of Dps
per cell decreased, while Fis-containing
cells and the quantity of Fis
per cell increased. After about
9 h, this change was complete and
the protein profile of nearly
all of the cells closely resembled that
of cells in raw wastewater.
The absence of a significant number of
residual Dps-containing
cells present during this recovery eliminates
the hypothesis of
subpopulation regrowth by rare surviving cells.
Instead, the results
indicate that the bulk of the cell community was
starving and
was resuscitated by nutrient
supplementation.
Nutrient supplementation of wastewater samples subjected to increased
chlorination (7 mg/liter, 1 h) resulted in a much slower
increase
in culturable fecal coliforms (Fig.
4). To test if this
might result
from the regrowth of a subpopulation of surviving
cells, cell protein
profiles were determined (Fig.
6C). As seen
previously (Fig.
6B),
2 h after nutrient supplementation, a change
in the protein
content of a small number of cells became evident,
in which Fis
abundance increased while Dps abundance decreased
(Fig.
6A and C,
circles). However, the rate of increase of such
cells was much slower
than observed previously. The abundance
of this class of fluorescent
cells agreed closely with the MPNs
after similar treatment (Fig.
4) and
represented only a fraction
of 1% of the total fluorescent cells. Such
cells may represent
rare survivors resulting from the increased level
of chlorination
which, as a result of continued chlorine injury, grow
at a reduced
rate.
| |
DISCUSSION |
These results indicate that standard chlorination of municipal
wastewater may often result in nutrient deprivation and loss of
coliform culturability rather than lethality. Utilization of selective
growth conditions precludes the ability of such cells to regain
culturability. However, nutrient addition and subsequent incubation
allow the resuscitation of nearly 100% of the initial coliform
community. The suggested holding time prior to wastewater analysis is
6 h, and holding times can be extended to a maximum of 24 h
(18). Discharged wastewater is, however, not held for any
time, and the exposure of the treated cell community to nutrients present in recreational water supplies, as well as the absence of
selective growth conditions, may well result in significant levels of
resuscitation of the coliform community. Such cells could represent a
previously unrecognized reservoir of organisms with significant public
health implications. We suspect that standard procedures in current use
induce the VNC state and therefore are responsible for the release of
large populations of viable and potentially culturable coliforms into
recreational water.
Single-cell quantitation of Fis, Dps, and DnaK levels was used as a
means of assessing physiological growth status. To our knowledge, this
is the first study employing cytosolic protein targets for such a
purpose. Since the method was compatible with the simultaneous use of a
16S rRNA-derived oligodeoxynucleotide probe, it would be feasible to
determine if the apparent variation in protein profile exhibited at the
single-cell level might result from taxon-specific differences in
response to chlorination. Such information could be useful for
improving our understanding of wastewater treatment processes. In
addition, the wide range of variation in cellular concentrations of Fis
and Dps corresponding to changes in growth state provide a highly
sensitive measure of bacterial physiological status. The occurrence of
the nongrowth state is accompanied by an increase in signal production
(Dps), which represents a fundamental difference from techniques which, instead, use 16S rRNA as a measure of physiological status. The cellular concentration of 16S rRNA varies only two- to threefold with
the growth state, and 16S rRNA typically decreases in abundance with
entry of the cell into the nongrowth state.
The protein profiling method was effective with uncultivated cells
derived from raw and treated wastewater. The ability to examine and
derive single-cell physiological information without resorting to
cultivation or incubation techniques provides a new opportunity to
obtain a real-time picture of bacterial physiology. As such, this
method may be useful for other studies in which the physiological
status of uncultivated bacteria is of interest. Current efforts concern
the application of this method to studies on pure-culture physiological
heterogeneity during the stationary phase.
| |
ACKNOWLEDGMENTS |
We thank T. J. Morris for helpful comments and R. Morita and
S. Giovannoni for encouragement.
This work was supported by a grant from the Department of Energy
(DE-FG02-93ER61701).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: E234 Beadle
Center for Genetics, University of Nebraska, Lincoln, NE 68588-0666. Phone: (402) 472-2769. Fax: (402) 472-8722. E-mail:
pblum{at}biocomp.unl.edu.
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Abstract
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