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Previous Article | Next Article 
Applied and Environmental Microbiology, April 2000, p. 1564-1571, Vol. 66, No. 4
0099-2240/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Comparison of Methods for Quantification of
Cytochrome cd1-Denitrifying Bacteria in
Environmental Marine Samples
Valérie
Michotey,1,*
Vincent
Méjean,2 and
Patricia
Bonin1
Laboratoire d'Océanologie et de
Biogeochimie, CNRS-UMR 6535, Centre d'Océanologie de
Marseille, Campus de Luminy, 13288 Marseille cedex
9,1 and Laboratoire de Chimie
Bactérienne, IBSM CNRS-UPR9043, 13402 Marseille cedex
20,2 France
Received 25 June 1999/Accepted 4 January 2000
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ABSTRACT |
Two PCR primer sets were developed for the detection and
quantification of cytochrome cd1-denitrifying
bacteria in environmental marine samples. The specificity and
sensitivity of these primers were tested. Both primer sets were
suitable for detection, but only one set, cd3F-cd4R, was suitable for
the quantification and enumeration of the functional community using
most-probable-number PCR and competitive PCR techniques. Quantification
of cytochrome cd1 denitrifiers taken from
marine sediment and water samples was achieved using two different
molecular techniques which target the nirS gene, and the
results were compared to those obtained by using the classical
cultivation method. Enumerations using both molecular techniques
yielded similar results in seawater and sediment samples. However, both
molecular techniques showed 1,000 or 10 times more cytochrome
cd1 denitrifiers in the sediment or water
samples, respectively, than were found by use of the conventional
cultivation method for counting.
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INTRODUCTION |
It is generally believed that only a
small fraction of environmental bacteria are recovered by current
cultivation techniques and that the quantification of microorganisms is
therefore biased. The most prominent methods which have been suggested
for studying this noncultivated fraction of indigenous community
bacteria are based on using nucleic acids. Techniques such as
most-probable-number (MPN) PCR and competitive PCR have been developed
to quantify specific groups of bacteria by amplifying the 16S fragment
in the ribosomal DNA (17, 25, 28, 31) or in the functional gene (15, 21, 35). In using studies which target metabolic function, in some cases all the organisms of a species or genus possess
the same metabolic function (nitrification or sulfate reduction, for
example). Using a probe which targets a specific part of the ribosomal
gene can therefore give an indication of the presence of the bacterial
group which is capable of that function. On the contrary, if the
function is spread among a variety of bacterial species, and only a
small number of strains of each species possess that function, it is
not possible to perform the classic approach of targeting the ribosomal
gene. In this case the conserved region of a functional gene may serve
as a suitable target. The use of a functional gene requires sufficient
genetic homology of the structural genes and the availability of
multiple sequences in order to reliably design primers. When the
function is widely spread over the phylogenic groups, the primers used for molecular detection become more degenerated. This increases the
risk of nonspecific annealing of the primer onto nontarget sequences,
which in turn leads to low specificity and low sensitivity of the
technique. Denitrification is a good example of a process which is
performed by a great diversity of bacterial strains which come from all
the major physiological groups, with the exception of
Enterobacteriaceae. The nitrite reductase gene is a key
enzyme for this metabolic process. Depending on the strain,
denitrifying bacteria possess either cytochrome
cd1 or copper nitrite reductase (NirS or NirK).
Different PCR primer systems for the amplification of the two nitrite
reductase genes have been designed (8, 16, 34). These
primers can be used to amplify nir genes in denitrifying strains from culture collections (8, 16), unidentified
isolates from different wastewater treatment plants, and DNA extracts
from activated sludge (16) or aquatic samples (8,
34). These primers have not yet been tested for the
quantification of denitrifying bacteria. In this study, we compared the
different methods used in the quantification of denitrifying bacteria
which contain the nirS gene encoding the
cd1 type Nir in environmental samples. Enumeration using the classical cultivation method is compared to two
quantitative molecular techniques, MPN-PCR and competitive PCR (cPCR).
The specificities and sensitivities of the two primer sets used in the
two molecular methods for counting are examined. This report not only
compares bacterial enumeration by traditional cultivation with
enumeration by molecular techniques but also, for the first time,
compares two different PCR-based methods for quantification.
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MATERIALS AND METHODS |
Bacterial strains and growth conditions.
A variety of
denitrifying and nondenitrifying bacterial strains (Table
1) were used to evaluate the specificity
of the designed PCR primers. All strains were grown aerobically at
30°C. Pseudomonas stutzeri ATCC 14405, P. stutzeri ATCC 11607, Pseudomonas fluorescens AK15,
Paracoccus denitrificans ATCC 19367, Flavobacterium sp. strain ATCC 33514, Achromobacter
cycloclastes ATCC 13867, Pseudomonas denitrificans ATCC
13867, Alcaligenes faecalis ATCC 8750, Bacillus azotoformans ATCC 29788, and Escherichia coli K-12 were
grown in Luria-Bertani (LB) medium (29). Pseudomonas
nautica 617 IPC 617/1.85, Marinobacter
hydrocarbonoclasticus ATCC 49840, Marinobacter sp.
strain CAB DSMZ 11572, marine isolates Al1, P3, 5, and P4, and
Vibrio sp. strain 45 (6) were grown in BHA medium
(24).
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TABLE 1.
Bacterial strains used in this study and test of the PCR
primer sets to amplify a fragment of the nirS gene
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Denitrification and nitrite reductase activity.
The strains
which had been isolated from the environmental samples were screened
for denitrifying activity. After anaerobic growth in the presence of 20 kPa of acetylene (in order to block the last step of denitrification),
nitrous oxide accumulation was measured using gas chromatography (as
described by Michotey and Bonin [22]). For the
detection of nitrite reductase activity, enzymatic assays were used.
The cells were harvested at the end of the exponential phase of growth,
washed twice with artificial seawater (ASW) (1), and
resuspended in 0.04 M Tris-HCl buffer (pH 7.6) containing benzamidine
(10 mM). Cell suspensions were passed through a French press. Any
intact cells and debris were eliminated by centrifuging for 10 min at
11,000 × g. The nitrite reductase activity of the
extracts was assayed spectrophotometrically (600 nm) using benzyl
viologen as the artificial electron donor in the presence of 20 mM
nitrite (2). Any copper nitrite reductase activity was
identified by becoming inhibited by the addition of 10 mM
diethyldithiocarbamate (DDC) (30, 38). In this experiment A. cycloclastes and P. nautica were used as
positive and negative controls, respectively.
DNA extraction from culture strains.
Genomic DNA was
obtained from pure cultures by treatment with lysozyme-sodium dodecyl
sulfate (SDS) followed by phenol-chloroform extraction and subsequent
precipitation using ethanol (29). The concentration of DNA
was determined spectrophotometrically following treatment with RNase.
A standard curve was constructed using a mixture of six marine cultures
of denitrifying strains of bacteria (P. nautica, M. hydrocarbonoclasticus, Marinobacter sp. strain CAB, and
marine isolates Al1, P3, and 5). The total number of cells in this
mixture was quantified by staining the cells with DAPI
(4',6'-diamidino-2-phenylindole dihydrochloride) and counting the
bacteria using an epifluorescence microscope as described previously
(26). Extraction of bacterial DNA was carried out using a
QIAamp DNA Mini Kit in accordance with the manufacturer's instructions
(Qiagen). A 0.4-ml volume of culture was centrifuged, and the
subsequent pellet was resuspended in 180 µl of buffer (20 mM
Tris-HCl, 2 mM EDTA, 1.2% Triton, and 20 mg of lysozyme/ml) and
incubated for 30 min at 37°C. A 20-µl volume of proteinase K and
200 µl of buffer AL (Qiagen) were added, and further incubation was
performed at 56°C for 30 min. This was followed by an additional
incubation at 90°C for 15 min. A 200-µl volume of ethanol was then
added to the lysate, and DNA purification was carried out accordingly
(Qiagen). Following the purification of nucleic acids, RNA was removed
by the addition of RNase (Boehringer Mannheim).
Oligonucleotide primers.
Two primer sets were designed
following the alignment of NirS amino acid sequences, which were
available in the gene banks. These sequences were retrieved from
GenBank and EMBL, and amino acid sequences were aligned with Clustal W
(32). Consensus regions that contained amino acids with less
degenerated codons were chosen. Primer sequences corresponded to
degenerate sequences of amino acids in the conserved regions of the
enzyme. The first (cd2R-cd8F) and the second (cd3F-cd4R) set of
primers correspond to the middle and the carboxyl half of the protein,
respectively. During completion of this article, Braker et al.
(8) reported the development of primers for nirS
detection, and their primer nirS6R appears to be the same as cd4R
(Table 2). In constructing an internal standard, an additional primer, cdst, was used. The sequence of the
cdst primer corresponds to that of the cd4R primer, but cdst has an
additional sequence on the 3' end corresponding to the sequence found
from position 1386 to position 1397 on the nirS gene of
P. stutzeri ATCC 14405 (see Table 2).
Construction of an internal standard for quantification of
nirS.
In order to obtain an internal standard, a shorter
fragment with the same primers at the ends was constructed. This
fragment (591 bp) is constructed by truncating the 3' end of a 750-bp
fragment of nirS of P. stutzeri ATCC 14405. Using
PCR with the cd3F and cdst reverse primer (see Table 2), the sequence
corresponding to the cd4R primer was added to the 3' end (Fig.
1). The internal standard was synthesized
by PCR using a "touchdown" protocol (12). The
hybridization temperature of the reaction was decreased 1°C every
second cycle from 60°C to a "touchdown" of 57°C, at which temperature 20 cycles were carried out. The denaturation,
hybridization, and elongation steps were performed for 30, 20, and
30 s, respectively. The main product from PCR was the 591-bp
fragment. After electrophoresis, the band was excised from the gel and
purified using an agarose gel DNA extraction kit (Boehringer Mannheim).
A 10-fold dilution of this fragment extract was used for amplification
with the cd3F and cd4R primers. The concentration of the internal
standard was estimated by comparing the intensity of its band on an
ethidium bromide-stained agarose gel to that of the 500-bp band from
the calibrated molecular weight standard.
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FIG. 1.
Scheme showing the construction of the internal standard
of 591 bp used for cPCR with primer set cd3F-cd4R. Dots represent
identical sequences.
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PCR amplification of nirS genes.
The two sets of
primers used for PCR (cd2R-cd8F and cd3F-cd4R) are based on
cytochrome cd1 gene sequences from denitrifying bacteria and amplify nirS fragments of approximately 272 and
750 bp. PCR amplifications of nir fragments were carried out
with 25 µl of reaction mixture (20 mM Tris-HCl, 50 mM KCl, 1.5 mM
MgCl2) containing 0.2 mM each deoxyribonucleotide
triphosphate, 160 pmol of each oligonucleotide primer, and 0.5 U of
Taq polymerase (Boehringer Mannheim). For PCR on the DNA
from pure cultures of denitrifiers, 50 ng of template DNA was used. To
prepare a standard curve for nirS quantification, DNA of
marine nondenitrifying bacteria (marine isolate Vibrio) was
added to the PCR mixture. This DNA corresponded to 106
cells of marine isolate Vibrio. One microliter of the
internal standard, corresponding to 2.4 × 104 DNA
templates, was also introduced in the PCR tube for cPCR.
Amplification was achieved using a minicycler (MJ Research) for 30 cycles. Template DNA was initially denatured for 2 min at 94°C, and
each cycle consisted of a 30-s denaturing step at 94°C, a 30-s
annealing step at 50°C for the cd3F-cd4R set of primers and 40°C
for the cd2R-cd8F set of primers, and a 40-s elongation step at
72°C. The final elongation step was extended for 3 min. The
amplification products were analyzed by electrophoresis on 1 or 1.5%
(wt/vol) agarose gels (Eurogentec) depending on the quantity of the PCR products.
Quantification of bacterial numbers.
In order to compare
classical and molecular methods for enumeration of denitrifying
bacteria, both techniques must be used on the same bacterial extract.
Methods used to extract bacteria from the environmental samples should
not damage the cell or DNA (breakage). For this reason, bacterial
extraction has been carried out in the absence of chemicals and
sonification. Microorganisms from 500 ml of a water sample collected in
the plume of the Rhône River (March 1999) were either centrifuged
at 16,000 × g for 10 min or filtered through a
0.2-µm-pore-size cellulose nitrate Whatman filter. The filters were
incubated in 5 ml of 0.2-µm-pore-size-filtered water from the same
sampling station for 3 h at 4°C. Cells remaining on the filter
were scraped off with a razor blade and pelleted by centrifugation at
22,000 × g for 10 min. Quantification of the denitrifying
bacteria in the sediment samples was performed using a sediment taken
from the mouth of the Rhône River (collected in March 1999). A
subsample of sediment (6.3 g [dry weight]) was obtained by mixing
with approximately 10 ml of the upper 2.5-cm layer of sediment.
Bacteria were removed from the sediment by the extraction technique of
Doria and Bianchi (13) modified as follows. Thirty
milliliters of sterile (0.2-µm-pore-size-filtered) seawater was added
to the sediment and mixed with a vortex agitator (Maxi-Mix Bioblock) at
1,200 rpm at 4°C for 1 h. Three consecutive extractions were
performed, and the three washings were mixed together. Cells were
collected by centrifugation at 22,000 × g for 10 min.
Bacterial counts using the culture and molecular methods were performed
on the suspended pellet.
For the bacterial count using cultivation techniques, aerobic
heterotrophic bacterial numbers were measured using the MPN culture
method. The medium was made up in filtered seawater
(0.22-µm-pore-size cellulose nitrate Whatman filter) supplemented
with NH4Cl (3 g/liter), sodium acetate (0.2 g/liter),
sodium succinate (0.2 g/liter), and Biotrypticase (2 g/liter). Numbers
of denitrifying bacteria were measured by the N2O-MPN
technique using the same medium amended with 10 mM nitrate and
acetylene according to Bonin et al. (5). Triplicate tubes
for each dilution were incubated 20°C for 15 days, and the positive
tubes were counted. Subsequent quantification could be made using
Cochran tables according to reference 9.
For bacterial counts using molecular techniques, cells were
concentrated either by filtration and centrifugation or by
centrifugation alone and were lysed using the same protocol as that for
the purification of bacterial DNA for the standard curve. For the
MPN-PCR technique, amplification was tested using three tubes per
dilution. Enumeration of denitrifiers was performed according to the
number of positive amplifications per dilution and the minimal number
of targets that could be amplified with the primers, and with the help
of Cochran tables (9). For cPCR, PCR was performed on a
serial dilution of the DNA from the samples and with a constant number (2.4 × 104) of internal fragments. For the
quantification of denitrifiers, the intensities of the two amplified
bands were measured and the number of target cells was calculated
according to the standard curve.
Densitometry.
To quantify PCR products, photographs of the
ethidium bromide-stained gels were scanned (Scanjet II CX;
Hewlett-Packard) and measurements of each band density were made
according to a vertical axis. Integrations were performed with PC
software (Image Master; Amersham Pharmacia Biotech). In order to
compare the band intensities from separate agarose gels, the
calibration band of the molecular weight standard, which was 700 bp
long and contained 70 ng (DNA QuantLadder; GenSura, Del Mar, Calif.),
was run on each gel.
Hybridization analysis of the nir products from total
DNA in bacterial cultures and environmental samples.
Products from
the amplification procedure, 50 ng of template DNA from pure cultures,
and 4 or 6.4 ng of DNA extracted from environmental samples (seawater
or sediment, respectively) were analyzed on agarose gels (1%
[wt/vol]). After electrophoresis, the DNA was transferred onto a
positively charged polyamide membrane (Schleicher & Schuell) by vacuum
transfer. The DNA was cross-linked to the membrane by UV light. The
probe corresponding to the nirS fragment of P. stutzeri ATCC 14405 was labeled by PCR with digoxigenin dUTP. The
membrane was hybridized using 30 ml of hybridization solution
(Boehringer Mannheim) containing the specific probe (25 ng
ml
1). Hybridization was carried out at 50°C overnight.
Following hybridization, the membrane was washed twice for 5 min at
room temperature in 100 ml of a solution containing 2× SSC (1× SSC is
0.15 M NaCl plus 0.015 M sodium citrate) and 0.1% (wt/vol) SDS and
twice for 15 min at 50°C with 100 ml of a solution containing 0.5×
SSC and 0.1% (wt/vol) SDS. Subsequently, the hybridization of the
digoxigenin-labeled probe was detected by an enzyme-linked immunoassay
with nitroblue tetrazolium/X-phosphate as the substrate as specified by
the manufacturer (Boehringer Mannheim).
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RESULTS |
Testing the specificity of the PCR primers used for
nirS detection.
We developed PCR primers to amplify
the nir fragment coding for cytochrome
cd1-Nir. The PCR primers were tested for
specificity on denitrifying strains containing either the cytochrome
cd1 or the Cu nitrite reductase gene, and on
nondenitrifying strains (Table 1). Among the screened strains, some had
already been identified as denitrifying (6, 10, 16), but we
also tested both primer sets on seven strains that we had previously
isolated from marine sediment and that could grow anaerobically in the presence of nitrate.
These strains were tested for nitrate utilization in anaerobiosis and
for nitrous oxide production when grown in the presence of acetylene
and nitrate (Table 1). Six out of seven strains were identified as
denitrifiers because they could utilize nitrate in anaerobiosis and
stoichiometrically reduce it to nitrous oxide. The seventh strain, the
marine isolate Vibrio sp. strain 45, did not accumulate
nitrous oxide under these conditions and was identified as being a
nitrate-ammonifying strain (6). All the tested marine isolates exhibited nitrite reductase activity. The type of nitrite reductase was determined using DDC, which selectively inhibits copper
nitrite reductase. The reductase activity of five out of six strains
was not inhibited by DDC (Table 1). The nitrite reductase activity of
the marine isolate P4 was inhibited by DDC, indicating that this strain
possesses a Cu nitrite reductase.
For PCR amplification, different annealing temperatures were evaluated
at intervals between 30 and 55°C. Some nonspecific bands disappeared
at temperatures higher than 40°C and at 50°C for the cd2R-cd8F and
cd3F-cd4R primer sets, respectively; however, some specific bands were
also lost. Therefore, annealing was performed at 40°C for the
cd2R-cd8F primer set and at 50°C for the cd3F-cd4R primer set. The
specificity of amplified fragments was checked by hybridization with a
fragment of P. stutzeri ATCC 14405 nirS. All
fragments of the expected size were recognized by the probe, indicating
that the amplified fragment corresponded to the nirS fragment (data not shown).
Sensitivity of the primer sets with pure target DNA, in the
presence of nontarget DNA.
In order to perform quantitative PCR,
it is necessary to test the sensitivity of the primers. Suitable
primer sets must be sensitive in order to detect the specific target
DNA of the sample, and their sensitivity must not vary with the
proportion of target DNA to nontarget DNA, since the percentage of
denitrifiers is not constant in environmental samples.
The sensitivity of both primer sets for the limit of detection of
denitrifiers was first tested with a constant number of target genes of
a mixture of marine cytochrome cd1 type
denitrifiers from our lab collection (corresponding to 7.2 × 104 cells of cytochrome cd1 type
denitrifiers) in the presence of DNA corresponding to various numbers
of nontarget marine microorganisms (between 0 and 7 × 106 cells of marine isolate Vibrio sp. strain
45). The tested percentage corresponded to that normally measured
in environmental samples. Figure 2 shows
the results of the amplification of nirS under these
conditions. With the cd2R-cd8F and cd3F-cd4R primer sets, the
intensity of the band was constant when the percentage of target
organisms varied from 100 to 10%. At 1%, a significant decrease of
28% in intensity was observed and a nonspecific band of approximately
1 kb appeared with the cd2R-cd8F primer set, whereas with the
cd3F-cd4R primer set a slight decrease in band intensity (about 8%)
was observed.
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FIG. 2.
Effect of the proportion of target to nontarget DNA on
the efficiency of PCR with primer sets cd3F-cd4R (A) and cd2R-cd8F
(B). Target DNA corresponds to 7.2 × 104 cells of a
mixture of six marine cytochrome
cd1-denitrifying bacteria. Nontarget DNA was
extracted from a Vibrio marine isolate.
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In order to determine the minimum number of target genes that yielded
fragment amplification (Fig. 3), in the
absence or in the presence of 106 nontarget DNA molecules,
PCRs were performed with serial dilutions of DNA. PCR of each dilution
was performed in triplicate. For the cd2R-cd8F primer set, fragment
amplification was obtained with a minimum of 120 target DNA molecules
present; for the same primer set in the presence of nontarget DNA,
7.2 × 103 target DNA molecules were necessary, i.e.,
60-fold more. On the other hand, using the cd3F-cd4R primer set, the
detection limits were 1.2 × 103 and 2.4 × 103 in the absence or in the presence of 106
DNA molecules of nontarget cells, respectively, i.e., only twofold more. The detection limit of the latter primer is almost constant in
the presence of various amounts of nontarget DNA.
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FIG. 3.
Determination of the detection limit of nirS
amplification from DNA extracted from a mixture of six marine
cytochrome cd1-denitrifying bacteria with primer
set cd3F-cd4R (A) or cd2R-cd8F (B), in the presence of nontarget DNA
extracted from 106 cells of a Vibrio marine
isolate. The number of target DNA molecules in each PCR tube is
indicated above each lane.
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In conclusion, our results show that both sets of primers are suitable
for the detection of denitrifiers in marine samples, but only one set
of primers (cd3F-cd4R) is suitable for their quantification. The
sensitivity of this primer and the intensity of the amplified band are
almost completely unaffected by the presence of differing quantities of
nontarget DNA. This primer set should therefore be used for the
quantification of denitrifiers in marine water and sediment samples by
molecular techniques (cPCR and MPN-PCR).
cPCR with the cd3F-cd4R primer set and construction of the
standard curve.
cPCR was performed with the cd3F-cd4R primer set,
which amplifies the 5' end of the nirS gene. In
noncompetitive PCR, this primer allowed the amplification of a number
of target DNA molecules ranging from approximately 2 × 103 to 107. It has been reported that cPCR is
more accurate when target and standard DNAs are present in equal
quantities in the PCR tube. In order to adjust the number of standard
DNA fragments to the center of the amplification range, 2.4 × 104 standard fragments were introduced into all the PCR
tubes. Under these conditions a standard curve was established using
the coamplification of the standard and of cytochrome
cd1 type denitrifier nirS genes extracted from known numbers of cells (a mixture of six denitrifying strains) in the presence of nontarget DNA (DNA extracted from 106 cells of a Vibrio marine isolate) or in the
presence of DNA extracted from 5 ml of a water sample (6 × 104 heterotrophic bacteria). PCR under these conditions
(with a constant amount of standard fragment) yielded amplification
products that were detectable on ethidium bromide-stained gels. These
corresponded to 7.2 × 106 to 1.2 × 104 cells in the amplification reaction mixture (Fig.
4). Each PCR was performed three times.
From the intensity of the two bands, the 750-bp/591-bp fragment ratios
were calculated and plotted against the number of target cells in the
PCR tube. The standard curve was fitted by the least-squares method
(Fig. 5). The standard curve was log-log
over almost 3 orders of magnitude. Amplification in the presence of
nontarget DNA, corresponding to DNA from a Vibrio marine
isolate or DNA from 5 ml of natural water (containing 6 × 104 heterotrophic bacteria), gave similar results.
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FIG. 4.
cPCR with primers cd3F-cd4R for construction of the
standard curve. The standard band (591 bp) corresponds to the
amplification of the internal standard (2.4 × 104
copies), and the 750-bp fragment corresponds to nirS
amplification of a mixture of six marine cytochrome
cd1-denitrifying bacteria added in different
amounts. PCR was performed in the presence of bacterial nontarget DNA
extracted from 106 cells of a Vibrio marine
isolate. MW, molecular weight standard. The number of target DNA copies
in each PCR tube is indicated above each lane.
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FIG. 5.
Standard curve for quantitative cPCR. The ratio of the
intensity of PCR products of target DNA (750-bp nirS
fragment) to standard DNA (591-bp fragment) was plotted against the
initial amount of target DNA (extracted from a known number of cells in
a mixture of six marine cytochrome
cd1-denitrifying bacteria) on a log scale. The
number of standard fragments was kept constant at 2.4 × 104 copies per tube. PCR was performed in the presence of
nontarget DNA extracted from 106 Vibrio sp.
strain 45 cells (triangles) or from 5 ml of seawater containing 6 × 104 heterotrophic bacteria (squares). Error bars,
standard deviations.
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Enumeration of cytochrome cd1-denitrifying
bacteria in two environmental samples by classical microbiological and
MPN-PCR and cPCR methods.
The partial extraction of bacteria from
sediment was performed by a very gentle technique in order to prevent
damage to bacteria which would result in underestimation in counting by
the cultivation technique. Enumerations of aerobic heterotrophic and
denitrifying bacteria were performed in seawater and sediment samples
by traditional MPN cultivation techniques (Table
3). The lower and upper limits correspond
to theoretical maximal and minimal limits calculated from Cochran
tables (9). The percentages of denitrifiers determined by
classical cultivation methods were 1 and 0.16% for the water and the
sediment sample, respectively. Cytochrome cd1
denitrifiers were also quantified by MPN-PCR and cPCR with the standard
curve previously obtained (Fig. 6).
Enumerations with cPCR were performed in triplicate. Table 3 gives the
means and the measured maximal and minimal experimental values. For
MPN-PCR, the lower and upper limits were calculated from the
characteristic number with 3 tubes per dilution according to
statistical tables (9). The 750-bp bands amplified from
environmental samples and the 591-bp band from the internal standard
were recognized by the probe of P. stutzeri ATCC 14405 nirS (data not shown). For all natural samples, enumeration
of cytochrome cd1 denitrifiers by MPN-PCR and
cPCR gave similar results. For water and sediment samples, results of
quantification by these molecular techniques were, respectively, 1 and
3 orders of magnitude higher than those obtained by classical culture
methods, which also included the total number of denitrifiers (those
possessing Cu nitrite reductase and those possessing cytochrome cd1 nitrite reductase). cPCR has been performed
on water samples treated by filtration and centrifugation, and counts
were not significantly different (data not shown). The results suggest that a large portion of denitrifiers in natural samples could not be
cultivated; only 0.1 to 10% of denitrifiers were recoverable on the
culture medium.
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TABLE 3.
Quantification of aerobic heterotrophic and denitrifying
bacteria by traditional cultivation and quantitative molecular
techniques with cd3F-cd4R primers
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FIG. 6.
Quantification by MPN-PCR and cPCR of cytochrome
cd1 denitrifiers in marine sediment (sed) (A)
and seawater (B) samples. For cPCR, 2.4 × 104 copies
of the internal standard (std) fragment were introduced initially into
the PCR tube. For MPN-PCR, results of triplicates of each dilution are
shown in the corresponding lane (+, positive amplification;  ,
negative amplification). The dilution of each DNA extract is indicated
above the lane. MW, molecular weight standards (700 and 500 bp).
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DISCUSSION |
Our main objective was to test the different quantification
methods (culture as well as molecular techniques) for bacteria sharing
the same metabolic pathway in marine samples. This study was performed
using phylogenetically diverse denitrifying bacteria. Denitrifiers are
ubiquitous facultatively anaerobic bacteria, and they reduce nitrate to
gaseous products only in anaerobiosis or in aerobic-anaerobic interface
environments. In marine samples, denitrifying populations are found
mainly in sediments but also in the water column, where their
activities are associated with particles (22). Marine
denitrifiers usually represent between 0.1 and 10% of the total
bacterial population in sediments (3), as well as being
found in the water column (our unpublished data on water of the
Mediterranean Sea or from the Rhône River plume). In order to
perform quantitative PCR on cytochrome cd1
denitrifiers, it was necessary to (i) use degenerated primers,
increasing the risk of nonspecific annealing of these primers onto
nontarget sequences, leading to putative low specificity and loss of
sensitivity in the techniques and (ii) to choose primers able to
amplify the nirS gene in the presence of a large background
of nontarget bacterial DNA, in the same proportion as that found in
environmental samples (90 to 99.9%). Furthermore, the efficiency of
the PCR should not depend on the proportion of target to nontarget DNA.
To quantify by using molecular techniques, the capacity of the primer
must be tested extensively in order to obtain reliable interpretable
results. In this study, we have tested the specificities and the
sensitivities of two sets of primers in order to use them for
quantitative PCR. The tested primers show the same range of specificity
as those already published (8, 16), but our designed primers
differ in that they allow not only detection but quantification. The
sensitivities of the two primer sets appeared to be quite different:
without nontarget DNA addition, amplification is 10-fold more sensitive
with the cd2R-cd8F primer set than with the cd3F-cd4R primer set;
after addition of nontarget DNA, the sensitivity with the cd3F-cd4R
primer set is slightly affected, whereas amplification is 10-fold less
sensitive using the cd2R-cd8F primer set. For quantification, the
amplification efficiency must stay constant whatever the proportion of
target to nontarget organisms. As it is probably impossible to find
environmental samples without denitrifying DNA, we have chosen to
introduce a bacterial marine DNA into PCR samples as the
nontarget DNA source. In order to approximate as closely as possible
the conditions encountered in particles or in sediment, we have chosen
to introduce a nondenitrifying strain that shares the same ecological
microniches and the same growth conditions as the denitrifiers.
Nitrate-ammonifying bacteria outcompete denitrifiers for nitrate in
aerobic-anaerobic interface marine environments (7, 22, 23)
and can be isolated from the same samples as denitrifiers. Thus, we
have chosen to use a nitrate-ammonifying bacterium (Vibrio
sp. strain 45) that was isolated from the same sediment and at the same
time as the other marine isolates used in this study (P3, 5, and P4)
(6).
The cd2R-cd8F primer set does not seem suitable for MPN-PCR and cPCR,
since the minimal number of target DNA molecules necessary to obtain
amplification varies with the proportion of target DNA to nontarget
microorganisms. In contrast, the intensity of the amplified band with
the cd3F-cd4R primer set is almost constant in the percentage range
usually encountered in marine environments. Our cd3F-cd4R primer set
would therefore be suitable for quantification of cytochrome
cd1 type denitrifiers in natural samples. Our
results doubtless show that a primer set might be suitable for
detection but not for quantification.
A standard log-log curve was constructed by using the cd3F-cd4R primer
set with a constant quantity of internal standard and nontarget DNA.
Using cPCR the yield of the two products is described as follows:
log(Nn1/Nn2) = log(N01/N02) + n × log(eff1/eff2) (21, 37). If the amplification
efficiency of the target amplicon (eff1) and that of the internal
standard (eff2) are equal, the ratio of products
(Nn1/Nn2) during any
cycle (n) depends solely on the ratio (molar or mass) of the initial
templates (N01/N02). In
this study, there is a slight difference in amplification efficiency, since for Nn1 = Nn2
the number of target nirS copies
(N01) is slightly lower than the number of
copies of the internal fragment (N02). In this
case, the quantification is still valid assuming that the eff1/eff2
ratio is a constant value and the amplification is in the exponential
phase (37). Few points of the standard curve were compared
with results obtained in the presence of nontarget DNA from natural
water instead of DNA from a marine isolate (Vibrio). The
data can be plotted on the curve showing that the PCR efficiencies in
the presence of nontarget DNA from a culture strain or from a natural
sample are comparable.
Quantification of cytochrome cd1 denitrifiers in
water samples or sediment samples was performed using MPN-PCR and cPCR
and was compared with the results of counts from classical cultivation techniques. Prior to enumeration, bacteria should be extracted from the
sediment without extracting the free DNA which is associated with the
sediment itself. In our experiments, due to the comparison of very
different methods for the quantification of bacteria, the method of
extraction and the concentration of bacteria must not interfere with
the cultivation or with the molecular enumeration techniques. Cell
damage which could cause an underestimate in the enumeration with
culture techniques should be avoided. The addition of detergents such
as Tween 80 can lead to an underestimation of 2 orders of magnitude for
cultivable bacteria with MPN compared to direct counting (our
unpublished results), and ultrasound treatment can lyse cells
(14). Vigorous shaking with filtered seawater is used in
this study for the extraction of bacteria from sediment. According to
Doria and Bianchi (13), about 60% of bacteria extracted from the sediment are from the interstitial water.
In this study, the two molecular techniques tested for quantifying
cytochrome cd1 denitrifiers gave very similar
results in both environmental samples. In the sediment sample,
quantification of denitrifiers by molecular techniques gave bacterial
counts 3 orders of magnitude higher than that found with classical
cultivation techniques. For water samples, the molecular techniques
gave numbers 5- to 10-fold higher than cultivation techniques. In these
experiments, enumeration using molecular techniques does not take into
account the denitrifiers with the copper nitrite reductase enzyme,
whereas cultivation methods count both types of denitrifier. It is
difficult to estimate the proportion of cytochrome
cd1 denitrifiers among the denitrifying
community, since, to our knowledge, no study has been specifically
dedicated to this subject. Several authors have, however, noticed that
cytochrome cd1 denitrifiers are more numerous
among isolated strains (10, 34). In our samples, it is
difficult to know whether cytochrome cd1
denitrifiers are a minority or if counting using the culture methods
underestimates the number of denitrifiers. Previous studies which have
compared enumeration using molecular and classical culture techniques
have shown that in some cases the two approaches give similar results (17, 19), but in other cases, authors found varying
correlations between DNA assay and CFU counting (15, 27). In
contrast, quantification by cPCR has shown a relatively strong
correlation with the number of bacteria introduced (20, 21).
In this study, we have obtained approximately the same counts using the
two quantitative molecular methods, but cPCR seems to be more precise
(lower variation of the result) and provides an internal control that
corrects the putative variation in the efficiency of the PCR due to the inhibitory compounds present in the environmental samples. The discrepancy in enumerations obtained by classical versus molecular techniques varies with sample type. Differences may be due to the
physiological states of natural bacterial communities. Indeed, it is
well known that bacteria may be in a viable state but not be cultivable
on a specific medium. Using molecular techniques, every bacterium that
contains the target DNA, whatever its physiological state, can be
counted. Conversely, counts using MPN culture techniques may give
varying results due to differences in the physiological state of the
bacteria, depending on the sample and the composition of the culture medium.
To follow up these experiments, we can begin by improving the protocol
used for the removal of bacteria from the sediment, using one
specifically dedicated to DNA studies (11). Then, using the
PCR techniques, it will be possible to quantify cytochrome cd1 type denitrifiers in additional
environmental samples using our cd3F-cd4R primer set along with new
primer sets which allow the amplification of the nitrite reductase
gene (nirK). This should enable the quantification of the
whole population of denitrifiers and have an important part to play in
determining the proportions of different types of denitrifying bacteria
in the functional community.
| |
FOOTNOTES |
*
Corresponding author. Mailing address:
Laboratoire d'Océanologie et de Biogeochimie, CNRS-UMR
6535, Centre d'Océanologie de Marseille, Campus de Luminy, Case
901, 13288 Marseille cedex 9, France. Phone: 33 491829336. Fax: 33 491826548. E-mail: michotey{at}com.univ-mrs.fr.
| |
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Abstract
Introduction
