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Applied and Environmental Microbiology, August 2001, p. 3677-3682, Vol. 67, No. 8
0099-2240/01/$04.00+0 DOI: 10.1128/AEM.67.8.3677-3682.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Bacterial Species Determination from DNA-DNA
Hybridization by Using Genome Fragments and DNA Microarrays
Jae-Chang
Cho1 and
James M.
Tiedje1,2,*
Center for Microbial
Ecology1 and Department of Microbiology
and Molecular Genetics,2 Michigan State
University, East Lansing, Michigan 48824
Received 28 November 2000/Accepted 18 May 2001
 |
ABSTRACT |
Whole genomic DNA-DNA hybridization has been a cornerstone of
bacterial species determination but is not widely used because it is
not easily implemented. We have developed a method based on random
genome fragments and DNA microarray technology that overcomes the
disadvantages of whole-genome DNA-DNA hybridization. Reference genomes
of four fluorescent Pseudomonas species were fragmented,
and 60 to 96 genome fragments of approximately 1 kb from each strain
were spotted on microarrays. Genomes from 12 well-characterized
fluorescent Pseudomonas strains were labeled with Cy dyes
and hybridized to the arrays. Cluster analysis of the hybridization
profiles revealed taxonomic relationships between bacterial strains
tested at species to strain level resolution, suggesting that this
approach is useful for the identification of bacteria as well as
determining the genetic distance among bacteria. Since arrays can
contain thousands of DNA spots, a single array has the potential for
broad identification capacity. In addition, the method does not require
laborious cross-hybridizations and can provide an open database of
hybridization profiles, avoiding the limitations of traditional DNA-DNA hybridization.
| |
INTRODUCTION |
Bacterial identification methods
currently used include analysis of morphological, physiological,
biochemical, and genetic data. In the last two decades, molecular
methods, especially 16S rRNA gene sequencing, have been a reliable aid
to the identification of diverse bacteria. Although the 16S rRNA method
has served as a powerful tool for finding phylogenetic relationships
among bacteria (24), because of its molecular clock
properties and the large database for sequence comparison, the molecule
is too conserved to provide good resolution at the species and
subspecies levels (2, 4, 9, 20, 23). The relationship
between 16S rRNA gene similarity and percent DNA-DNA reassociation is a
logarithmic function in which the sequence similarity within a species
(>70% DNA relatedness) is expected to be >98% (3), and
the similarity among different species in a genus, e.g., fluorescent
Pseudmonas spp., is 93.3 to ~99.9% (11).
Considering the high sequence conservation and relative standard errors
at 98 and 90% sequence similarities of 19 and 8%, respectively
(5), 16S rDNA analysis results on closely related strains
could be inaccurate and inconsistent with the results obtained by other
methods. Incongruity between genome structure and 16S rDNA sequence
similarity was also reported (8). Since many important
ecological and clinical characteristics of bacteria, such as
pathogenicity, competitiveness, substrate range, and bioactive molecule
production, vary below the species level, methods with higher
resolution than that of 16S rDNA sequencing are needed.
DNA-DNA hybridization is one method that provides more resolution than
16S rDNA sequencing, and the 70% criterion (22) has been
a cornerstone for describing a bacterial species. In spite of these
values, the method is not popular. Major disadvantages are the
laborious nature of pairwise cross-hybridizations, the requirement for
isotope use, and the impossibility of establishing a central database.
Here, we propose a new approach to identify and type bacteria based on
genomic DNA-DNA similarity that eliminates the above disadvantages. The
method takes advantage of the capacity provided by microarray
technology (6). Bacterial genomes are fragmented randomly,
and representative fragments are spotted on a glass slide and then
hybridized to test genomes. Resulting hybridization profiles are used
in statistical procedures to identify test strains. Importantly, a
database of hybridization profiles can be established. This paper
describes this method and its evaluation with previously characterized
fluorescent Pseudomonas strains.
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MATERIALS AND METHODS |
Bacterial strains and DNA extraction.
The
Pseudomonas strains used in this study were
Pseudomonas fluorescens ATCC 13525T, P. fluorescens ATCC 17397, P. fluorescens ATCC 17400, P. fluorescens ATCC 17467, P. fluorescens ATCC
33512, P. marginalis LMG 5039, P. chlororaphis
ATCC 9447, P. chlororaphis ATCC 17811, P. aureofaciens ATCC 13985T, P. putida ATCC
12633T, P. aeruginosa ATCC 15692, and P. aeruginosa ATCC 17429. All strains were routinely cultivated at
30°C in nutrient broth medium (Difco, Detroit, Mich.). Genomic DNAs
from the strains were extracted and purified using Genomic Tips
(Qiagen, Valencia, Calif.) with Genomic DNA Buffer Set (Qiagen). The
concentration of DNA was determined by UV spectrophotometry and with
SpotCheck (Sigma, St. Louis, Mo.).
Microarray fabrication.
Genomic DNAs from four fluorescent
Pseudomonas strains (P. fluorescens ATCC
13525T, P. chlororaphis ATCC 9447, P. putida ATCC 12633T, and P. aeruginosa ATCC
15692, hereafter termed the reference strains) were fragmented by bead
beating to ensure randomness, and the fragments were size fractionated
(1 to 2 kb) by agarose gel electrophoresis. The QIAquick gel extraction
kit (Qiagen) was used to elute and purify DNA from the agarose gel. The
genomic DNA fragments were inserted into pPCR-Script Amp vector
(Stratagene, La Jolla, Calif.) and then PCR amplified with the T3-T7
promoter primer set. Amplified genomic DNA fragments were purified with a QIAquick 8 PCR purification kit (Qiagen) and quantified with PicoGreen (Molecular Probes, Eugene, Oreg.).
Purified DNAs were resuspended (200 ng/µl) in 3× SSC (1× SSC is
0.15 M NaCl plus 0.015 M sodium citrate) and printed (ca. 1 nl/spot) on
CMT-GAPS amino silane-coated slides (Corning Co., Corning, N.Y.).
Fragments from P. fluorescens, P. chlororaphis, P. putida
and P. aeruginosa (92, 90, 96, and 60, respectively) were spotted in duplicate (Fig.
1). The yeast STE gene
(pheromone receptor gene; GenBank accession no. M12239) was spotted as a positive control, and the yeast ACT gene (actin gene;
GenBank accession no. L00026), lambda DNA, and water were spotted as negative controls. PCR primer pair STE3F1 (CCC CTT CAAAAT TGG AGC
TTG C) and STE3R1 (CCC CCT TTA GCA TGG CAT TCA) and
pair ACT1F1 (GAT GGA GCC AAA GCG GTG A) and ACT1R1 (GCG
CTT GCA CCATCC CAT T) were used to amplify yeast genes
STE and ACT, respectively.
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FIG. 1.
Format of the array used in this study. Genome fragments
from four reference strains were spotted in duplicate (upper and lower
halves). Positive (yeast gene STE) and negative (yeast gene
ACT, lambda DNA, and water) controls are indicated by
circles and squares, respectively. Pseudocolors indicate the ratio
(R) between the Cy3 channel and Cy5 channel (green,
R > 1; yellow, R = 1; red,
R < 1).
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After drying, the slides were processed with the succinic anhydride
blocking method according to the manufacturer's protocol
and stored at
room temperature until
use.
Genomic DNA labeling and hybridization.
Genomic DNAs (1 µg) from all the strains listed, including reference strains, were
labeled with FluoroLink Cy3-dCTP (Amersham Pharmacia, Piscataway, N.J.)
by random priming (High Prime; Roche, Indianapolis, Ind.) and used as
test DNAs. Mixtures of genomic DNA (1 µg) from the four reference
strains (1:1:1:1) used for microarray fabrication were labeled with
FluoroLink Cy5-dCTP (Amersham Pharmacia) and used as reference DNA for
signal ratio calculation (Cy3-test/Cy5-reference). Yeast gene
STE (10 ng) was included in each labeling reaction as a
positive control as well as an internal standard (IS; Cy3-IS and
Cy5-IS) for labeling-efficiency correction.
The arrays were prehybridized in prehybridization buffer (3.5× SSC,
0.1% sodium dodecyl sulfate [SDS], 10 mg of bovine serum
albumin per
ml) for 20 min at 65°C, hybridized with approximately
1 µg of Cy3-
and Cy5-labeled DNA mixture (1:1) in hybridization
buffer (3× SSC,
0.1% SDS, 0.5 mg of yeast tRNA per ml) at 65°C
overnight, and then
washed once with primary wash buffer (0.1×
SSC, 0.1% SDS) at room
temperature for 5 min and twice with secondary
wash buffer (0.1× SSC)
for 5
min.
Scanning and data processing.
Hybridized arrays were scanned
with a GenePix 4000 laser scanner (Axon, Foster City, Calif.). Laser
lights of wavelengths at 532 and 635 nm were used to excite Cy3 and Cy5
dye, respectively. Fluorescent images were captured as
multi-image-tagged image file format and analyzed with GenePix Pro 3.0 software (Axon). The ratio (R) of the extent of
hybridization between test DNAs and reference DNAs was derived from a
median value of pixel-by-pixel ratios. By using this approach to
calculate R, nonspecific signals, which appear in both
wavelength images, had less of an effect than when the mean values of a
whole spot were used.
Hybridization signal ratios (
R) between test DNA and
reference DNA (Cy3-Test/Cy5-Ref) were calculated and corrected with the
correction factor (
c = Cy5-IS/Cy3-IS) from the internal
standard
(yeast gene
STE) (corrected signal ratio
R' =
c × [Cy3-Test/Cy5-Ref]).
Spearman
correlation coefficients (
r) were calculated to find
relationships between hybridization patterns and transformed to
a
percentage scale. Unweighted arithmetic average clustering (UPGMA)
was
used for hierarchical data ordination. For characterizing
the shape of
hybridization signal distribution, the evenness (
E)
value of
each spotted genome fragment was calculated based on
information theory
using
E = (
p log
p)/log
q (
7,
15),
where
p is the relative
proportion of hybridization signal ratio
(
R') and
q is the total number of hybridizations performed. Since
the
distribution of the calculated
E values was highly skewed
(skewness =
0.855), the
E values were normalized by
arc cosine
transformation. The arc cosine-transformed evenness value,
E,
was used to represent the degree of
conservation of each genome
fragment.
Microsoft Excel, Systat (SPSS, Chicago, Ill.), and NTSYS-pc (Exeter
Software, East Setauket, N.Y.) were used for all statistical
calculations.
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RESULTS AND DISCUSSION |
Reproducibility.
The ratio of Cy5 to Cy3 incorporation
(Cy5-IS/Cy3-IS) during the DNA labeling was 1.04 ± 0.32 for all
experiments. An incorporation ratio (c = Cy5-IS/Cy3-IS)
obtained for each microarray was used as a correction factor for
hybridization signal calibration (corrected signal ratio R' = c × [Cy3-Test/Cy5-Ref]). The correction factor, however, did not affect the correlation coefficient calculation, since
the correlation coefficient is independent of any constant (e.g.,
c).
In order to test the reproducibility of array hybridization, seven
arrays were hybridized to genomic DNAs of
P. fluorescens ATCC 13525
T (three times),
P. putida ATCC
12633
T (two times), and
P. aeruginosa ATCC 15692 (two times). Figure
2 shows the scatter
plot representation of triplicate hybridization
profiles of
P. fluorescens ATCC 13525
T. The arrays hybridized to
P. fluorescens ATCC 13525
T (triplicate),
P. putida ATCC 12633
T (duplicate), and
P. aeruginosa ATCC 15692 (duplicate) showed
similarity values of
>97.5% (
r > 0.949,
P < 0.0001), 95.3%
(
r = 0.906,
P < 0.0001), and 94.1% (
r = 0.882,
P < 0.0001), respectively.
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FIG. 2.
Scatter plot diagram of hybridization profiles of
P. fluorescens ATCC 13525T. Results from
triplicate hybridization experiments (r2 = 0.94) are displayed, and each axis (x, y, and
z) represents the log-transformed hybridization signal
ratios from each experiment.
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Resolution.
Regression analysis showed a good agreement
between DNA-DNA reassociation values and the similarity coefficients
obtained from this study (Fig. 3). The
coefficient of determination (r2) was 0.713. Order 1 of linear relationship and the regression coefficient (slope,
0.718) indicate that the microarray method is similar in resolution to
the whole-genome DNA-DNA hybridization method. The two methods lost
their linear relationships below 50% DNA-DNA similarity, which
approximately corresponds to a 60% similarity coefficient obtained by
the DNA microarray method.
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FIG. 3.
Relationship between previously reported whole-genome
DNA similarity values (12, 13) and similarity values
obtained by the microarray method. The solid line and dotted lines
indicate the regression curve and 95% prediction interval,
respectively.
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A similar result was observed with the relationship between repetitive
extragenic palindromic (REP)-PCR genomic DNA fingerprint
similarity and
percent DNA similarity values (
16). REP-PCR fingerprinting
(
17) lost resolution when applied to strains of less than
70%
DNA similarity, indicating that REP-PCR fingerprinting is capable
of resolving relationships only among very closely related strains.
The
DNA chip method used here showed linearity over a broader
span of DNA
similarity values (50 to 100%) but provided slightly
less resolution
at >70% DNA similarity values than for the REP-PCR
fingerprinting
method. The microarray method, however, can still
resolve closely
related strains and, more importantly, provides
resolution over the gap
between REP-PCR fingerprinting and 16S
rDNA analysis
(1).
We have considered the case where different strains of the same species
have differences in genome size, e.g.,
Escherichia coli K-12
versus O157 (GenBank accession no.
U00096 and
AE005174,
respectively).
This scale of difference (1 of 5 Mb) should not
invalidate our
approach, although our percent similarity should
be slightly higher
than the average percent similarity from whole-genome
DNA-DNA
hybridization.
Cluster analyses.
The overall topology of the dendrogram based
on cluster analysis of similarity coefficient matrix was consistent
with the phylogenetic tree obtained from 16S rDNA sequence data
(11) except for P. putida and P. aeruginosa clusters (Fig. 4). The P. aeruginosa group clustered with the P. fluorescens and P. chlororaphis groups at a higher
similarity (67.9%) than for the P. putida group (39.0%),
of which generally shows greater 16S rDNA similarity to P. fluorescens and P. chlororaphis than to P. aeruginosa (11). However, a similar result to our
array data was reported by Palleroni et al. (13) using
DNA-DNA similarity values, where the P. aeruginosa group was
found to be a closer relative to P. fluorescens group than
was the P. putida group.
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FIG. 4.
Similarity dendrogram (UPGMA) of microarray
hybridization profiles of fluorescent Pseudomonas strains.
The solid line indicates a cutoff value at which all different strains
tested were resolved. The dashed line indicates species-level
resolution that corresponds to 70% whole-genome DNA hybridization.
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All replicate experiments showed similarity coefficients of
94%
(
r = 0.88), and all different strains were
distinguished
at similarity values of
91% (
r = 0.82). Hence, similarity coefficients
of <92 to 94%
(
r = 0.84
to 0.88) can reliably define different
hybridization groups. Using the regression equation from Fig.
2, a
cutoff value of 77% was calculated to correspond to a 70%
DNA
similarity value to define "species" (
22). This cutoff
resolved
the
P. fluorescens, P. chlororaphis, P. aeruginosa,
and
P. putida species but did not resolve
P. marginalis from
P. fluorescens or
P. aureofaciens from
P. chlororaphis, but these latter
pairs
of species are known to be very similar by other methods.
P. aureofaciens ATCC 13985
T and
P. chlororaphis ATCC 9447 show 85% DNA similarity (
13),
and the 16S rDNA similarity between
P. aureofaciens and
P. chlororaphis and between
P. fluorescens and
P. marginalis is 99.5 and 99.9%,
respectively (results from
different strains) (
11).
P. marginalis is also
reported to have very similar characteristics to
P. fluorescens and was previously classified as
P. fluorescens (
10,
14,
18,
21). Hence, it appears that
this method has promise for providing
reliable guideline values for
species or genomovar
resolution.
Either the array hybridization profiles (signal ratios) or raw images
(microarray scans) can be archived in a World Wide Web
server to
establish the central database so that researchers can
compare their
results with the database and consequently identify
their strains,
analogous to retrieval of RDP
data.
The more reference strains whose genome fragments are spotted on the
array and more genome fragments spotted from the reference
strains, the
greater the resolution and the consistency of this
approach are likely
to be. We used 338 genome fragments from four
reference strains in our
test model. Considering that the average
genome size of fluorescent
Pseudomonas strains is approximately
5 Mb and that the size
of the genome fragments used is 1 to 2
kb, the array used in this study
samples approximately 1 to 3%
of a genome. However, supposing that
each spot (genome fragment)
tests individual genetic characteristics
quantitatively, the array
performed 338 individual tests for
determining the similarity
coefficients for one test strain. Sokal and
Sneath (
19) suggest
that more than 60 characters give
significant reliability for
similarity coefficients and enough
information for numerical taxonomy.
In fact, all of our similarity
coefficients were statistically
significant (
P < 0.0001).
Cluster analysis was also performed on the hybridization patterns of
all 338 spotted fragments across all strains tested (Fig.
5). Four main clusters were found at a
cophenetic similarity of
70%. Main clusters F, C, A, and P mainly
comprised the fragments
from the four reference strains,
P. fluorescens (98.7%),
P. chlororaphis (94.1%),
P. aeruginosa (91.8%), and
P. putida (100%).
Minor clusters
V, W, X, and Z comprised the genome fragments from
different reference
strains. In a gene expression data analysis, such
clusters indicate
that these genes tend to turn on and off
simultaneously, but the
grouping in this study indicates only that the
hybridization patterns
of the cluster members are similar to a certain
degree. If the
genome fragments from the different reference strains
form such
a cluster, it suggests but does not confirm conserved
sequences.
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FIG. 5.
Similarity dendrogram (UPGMA) of hybridization profiles
of 338 genome fragments spotted on the microarray. Clusters F (98.7%),
C (94.1%), A (91.8%), P (100%), and Y (100%) comprise genome
fragments from the reference strains P. fluorescens ATCC
13525T, P. chlororaphis ATCC 9447, P. aeruginosa ATCC 15692, and P. putida ATCC
12633T. Clusters V to Z comprise genome fragment from
different reference strains, except cluster Y.
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To conveniently find conserved and unique (variable) sequences in our
fragment collection, we calculated an evenness index
(
E)
(
7,
15) from hybridization signal ratio profiles of each
spotted genome fragment across the test strains (Fig.
6). If a
fragment is extremely conserved
in all test strains (e.g., rRNA
genes), the angle
(
E) would show its minimum value (0°).
Genomic fragments showing a small angle (high evenness) tend to
show
high hybridization signal ratio with low standard deviation,
indicating
that they showed as high a hybridization signal as
many genomes tested
and hence can be considered conserved sequences.
In contrast, genomic
fragments with a large angle (low evenness)
tend to show a low average
signal ratio with high standard deviation,
indicating that they showed
appreciable hybridization signal only
to the closely related strains
and hence are considered variable
sequences.
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FIG. 6.
(a) Evenness value (E) scatter
diagram, with average and SD of log hybridization signal ratio. (b)
E values by genome fragment, ID 1 to 92, 93 to 182, 183 to 278, and 279 to 338 originated from P. fluorescens ATCC 13525T, P. chlororaphis
ATCC 9447, P. putida ATCC 12633T, and P. aeruginosa ATCC 15692, respectively. The solid line and dotted
lines (horizontal) indicate average and SD, respectively.
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The average angle (
E) for all data was
35.0° ± 12.5°. Fifty-one (15.1%) fragments with
E values lower
than 1 standard deviation (SD)
below the mean (<22.5°) (Fig.
6b)
showed appreciable hybridization
signal (
R' > 1) for the genomic
DNAs from closely related
species, e.g., species pair
P. fluorescens and
P. marginalis and pair
P. chlororaphis and
P. aureofaciens.
The majority of these originated from two reference
strains,
P. fluorescens ATCC 13525
T and
P. chlororaphis ATCC 9447, including only five fragments
from the
clusters V, W, X, and Z in Fig.
5. Fragments showing
appreciable
hybridization (
R' > 1) for all strains tested (e.g.,
E << 10°) were not found on our
array.
Sixty-eight (20.1%) fragments with
E values
of 1 SD above the mean (>47.5°) showed appreciable hybridization
only
when hybridized to the reference strains. The rest of the
fragments
(64.8%) showed an intermediate level of conservation. While
four
main clusters (F, P, C, and A) (Fig.
5) contain all genome
fragments
with
E values of 22.5° to 47.5°
(species level), the
groups of highly variable sequences
(
E value > 47.5°)
(strain level) are
also located in the main clusters (Fig.
5).
It is noteworthy that the
variable and conserved sequences cannot
be reliably identified by
cluster analysis (Fig.
5), but are easily
revealed by
E values.
Using the calculated
E values, we can also
construct a relationship between
E value and
taxonomic distance
(Fig.
7), where
valley-shaped regions could be considered to be
caused by selection
pressure, resulting in subsequent speciation
events. The genome
fragments with low
E values have
almost
identical sequences and are distributed over a wide taxonomic
range,
while the fragments with high
E values are
distributed
over a narrow taxonomic range. When our empirical results
(
E values) were applied to this diagram, the
degree of conservation
within strain level, species level, closely
related species level,
and genus level correspond roughly to
E values of >50°,
50° to 20°, 20° to
10°, and <10°, respectively. Additionally,
a taxonomic
distance [
D1/tan(
)] can be calculated
{
D1/tan() = 1/[tan(
E)]}. The range of
E values for species
level (>20°) in this
study resulted in a
D1/tan () of 2.74,
indicating a radius of taxonomic range for a species. This alternative
to calculating taxonomic distance by using genome-wide analyses
may be
useful for delineating species, although the values would
be expected
to vary with microbial groups.
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FIG. 7.
Proposed relationship between
E value and taxonomic distance in taxonomic
continuum. Taxonomic continuum is multidimensional, and hence, genetic
similarity peaks could also be a multidimensional structure, but
diagram is drawn as shown (two-dimensional) for convenience. Broken
lines indicate the degree of conservation of genome fragments with
different E values.
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Conclusions.
This study provides a proof of concept for
identification of bacteria using DNA-DNA hybridization with DNA
microarrays, as tested on four reference strains of fluorescent
Pseudomonas spp. With current technology of microarray
fabrication, 100,000 genomic fragments can be spotted on a chip. Hence,
it is feasible to test 1,000 reference strains with 100 genome
fragments from each reference strain. Such an array should be enough to
cover the full taxonomic range of either gram-negative or gram-positive
bacteria. This approach also appears to be useful for determining the
genetic distance among bacteria as well as for identifying bacterial species.
Major improvements and advantages over the traditional DNA-DNA
reassociation approach are that our method does not require
cross-hybridization to find genetic relationship between test
strains,
does not use an isotope, and can utilize an open database
of
hybridization profiles when standard genome chips for bacteria
are
available.
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ACKNOWLEDGMENTS |
We thank Alison Murray for helpful discussion, the
MSU-Arabidopsis facility, and Syed Hashsham for microarray facilities.
This research was supported by NSF grant DEB-0075564 and the Center for
Microbial Ecology under NSF grant DEB-9120006.
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FOOTNOTES |
*
Corresponding author. Mailing address: Center for
Microbial Ecology, Plant and Soil Sciences Bldg., Michigan State
University, East Lansing, MI 48824. Phone: (517) 353-9021. Fax:
(517) 353-2917. E-mail: tiedjej{at}msu.edu.
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Applied and Environmental Microbiology, August 2001, p. 3677-3682, Vol. 67, No. 8
0099-2240/01/$04.00+0 DOI: 10.1128/AEM.67.8.3677-3682.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
