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Applied and Environmental Microbiology, December 1998, p. 4983-4989, Vol. 64, No. 12
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Novel Euryarchaeotal Lineages Detected on Rice
Roots and in the Anoxic Bulk Soil of Flooded Rice Microcosms
Regine
Großkopf,
Stephan
Stubner, and
Werner
Liesack*
Max-Planck-Institut für terrestrische
Mikrobiologie, D-35043 Marburg, Germany
Received 8 May 1998/Accepted 10 September 1998
 |
ABSTRACT |
Because excised, washed roots of rice (Oryza sativa)
immediately produce CH4 when they are incubated under
anoxic conditions (P. Frenzel and U. Bosse, FEMS Microbiol. Ecol.
21:25-36, 1996), we employed a culture-independent molecular approach
to identify the methanogenic microbial community present on roots of
rice plants. Archaeal small-subunit rRNA-encoding genes were amplified directly from total root DNA by PCR and then cloned. Thirty-two archaeal rice root (ARR) gene clones were randomly selected, and the
amplified primary structures of ca. 750 nucleotide sequence positions
were compared. Only 10 of the environmental sequences were affiliated
with known methanogens; 5 were affiliated with Methanosarcina spp., and 5 were affiliated with
Methanobacterium spp. The remaining 22 ARR gene clones
formed four distinct lineages (rice clusters I through IV) which were
not closely related to any known cultured member of the
Archaea. Rice clusters I and II formed distinct clades
within the phylogenetic radiation of the orders
"Methanosarcinales" and Methanomicrobiales.
Rice cluster I was novel, and rice cluster II was closely affiliated
with environmental sequences obtained from bog peat in northern
England. Rice cluster III occurred on the same branch as
Thermoplasma acidophilum and marine group II but was only
distantly related to these taxa. Rice cluster IV was a deep-branching
crenarchaeotal assemblage that was closely related to clone pGrfC26, an
environmental sequence recovered from a temperate marsh environment.
The use of a domain-specific oligonucleotide probe in a fluorescent in
situ hybridization analysis revealed that viable members of the
Archaea were present on the surfaces of rice roots. In
addition, we describe a novel euryarchaeotal main line of descent,
designated rice cluster V, which was detected in anoxic rice paddy
soil. These results indicate that there is an astonishing richness of
archaeal diversity present on rice roots and in the surrounding paddy soil.
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INTRODUCTION |
It has been estimated that about
80% of atmospheric CH4, one of the most important
greenhouse gases, is derived from biological processes (18).
One of the major sources of CH4 is flooded rice paddies,
which annually emit about 60 Tg of CH4 into the atmosphere (28). Since CH4 production is a strictly
anaerobic process, it has been assumed that methanogenic microbial
activity in flooded rice paddies occurs only in the anoxic bulk soil
with acetate and H2 plus CO2 as the major
substrates (34). The root surface (rhizoplane) and the
adjacent rhizosphere soil are at least partially oxygenated due to
diffusion of atmospheric O2 into the root system via the
gas vascular system of rice plants (8, 33). The root system
itself has therefore never been considered an important methanogenic
habitat. However, Frenzel and Bosse (12) demonstrated that
isolated roots excised from rice plants that were 40 and 71 days old
immediately produced CH4 when they were incubated under
anoxic conditions, even though no attempt had been made to avoid
exposure to oxygen during washing of the root material. A second series
of in vitro experiments showed that CH4 production increased from the flowering stage (~90-day-old rice plants) to the
ripening stage (~140-day-old rice plants) and that potential CH4 production on roots accounted for about 8% of the
total CH4 production measured for roots plus soil together
in the root-occupied 1-cm surface layer (6). Using diether
lipids as signature compounds, workers have also determined that
archaea, probably methanogens, are predominant members of the microbial
communities on roots of mature rice plants grown at the International
Rice Research Institute in the Philippines (29).
These observations prompted us to use a molecular retrieval approach
with archaeal small-subunit (SSU) rRNA-encoding gene (rDNA) sequences
in order to identify the methanogenic microbial community
associated with roots of flooded rice. Similar
cultivation-independent environmental studies have resulted
in completely new insights into the naturally occurring diversity of
members of the domains Bacteria and Archaea in
various environments (23). Recently, the use of such
approaches has demonstrated the ubiquity of phylogenetically deep-branching crenarchaeota in cold and moderate-temperature environments (5, 9, 17, 21, 25, 32) and the presence of numerous novel bacterial lineages in a Yellowstone National Park hot pool (19).
Our molecular survey resulted in the detection of some environmental
sequences that are closely affiliated with known groups of methanogens.
However, the majority of the SSU rDNA clones retrieved from rice roots
formed several distinct lineages which could not be assigned to any
previously known cultured member of the Archaea. In a
previous study, Methanosaeta spp. and
Methanobacterium spp. were found to be the numerically
dominant acetoclastic and hydrogenotrophic methanogenic organisms
in the anoxic bulk soil of flooded rice microcosms (15). In
that study, nine environmental sequences which could not be assigned to
any known methanogen were recovered from the bulk soil. Because six of
these sequences clustered with phylotypes detected on the root systems
of rice, we describe the phylogeny of these nine bulk soil sequences
together with our rice root data.
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MATERIALS AND METHODS |
Source of root material.
Rice plants (Oryza
sativa var. Roma, type japonica) were grown in two flooded
microcosms for 84 or 90 days under conditions described previously
(12, 15). Rice root samples obtained from these two
microcosms were used as source material for molecular retrieval of
archaeal SSU rDNA sequences. The root material was washed with careful
shaking in phosphate-buffered saline (PBS) (7 mM
Na2HPO4, 3 mM NaH2PO4,
130 mM NaCl; pH 7.2) to remove adhering soil particles.
Preparation of root samples.
The washed root samples taken
from the 84- and 90-day-old microcosms were processed differently prior
to extraction of total DNA. The rice roots taken from the 84-day-old
microcosm were shaken with glass beads (diameter, 0.1 mm) as described
by Gilbert and Frenzel (14). Subsequently, this root
material was suspended in 1 ml of extraction buffer (100 mM Tris-HCl,
50 mM EDTA, 500 mM NaCl, 1 mM dithiothreitol [pH 8.0]) and
homogenized for 30 min with a tissue grinder (B. Braun Diessel Biotech
GmbH, Melsungen, Germany). The rice roots taken from the 90-day-old
microcosm were lyophilized, and 150 mg of dried root material was
subsequently pulverized with a mortar under liquid N2. The
pulverized root material was resuspended in 1 ml of extraction buffer.
Extraction of total DNA from rice roots.
The same extraction
protocol (which included enzymatic lysis of microbial cells, as well as
isolation and purification of total root DNA) was used for the two
different rice root batches. The cells were lysed by successive
treatments with lysozyme, proteinase K, and sodium dodecyl sulfate
(SDS). After three cycles of freezing and thawing (freezing at 
70°C
for 2 min, followed by heating at 65°C for 2 min), 2 mg of lysozyme
in 40 µl of H2O was added to the suspension, and the
preparation was incubated for 1 h at 37°C. Proteinase K (0.1 mg)
and 50 µl of 10% SDS (corresponding to a final SDS concentration of
0.5%) were added to the reaction cocktail, and the preparation was
incubated for 1 h at 37°C. Then a 10% SDS solution was added
until the final concentration of SDS was 2%. The preparation was
incubated for 10 min at 65°C. Finally, the suspension was mixed with
0.4 ml of 5 M potassium acetate and incubated for 20 min on ice; this
was followed by centrifugation for 15 min at 13,000 × g. The supernatant was transferred to a new reaction vessel.
Total root DNA was recovered by phenol-chloroform extraction followed
by isopropanol precipitation and centrifugation for 15 min at
13,000 × g. The DNA pellet was lyophilized and finally resuspended in 200 µl of deionized water. The amount of extracted DNA
was estimated by electrophoresis of 5-µl aliquots on a 0.8% agarose
gel and comparison to a HindIII digest of 
DNA. The
gel was stained with ethidium bromide.
PCR amplification, cloning, and sequencing.
The
oligonucleotide primer system and PCR conditions used for amplification
of the archaeal SSU rDNA fraction of the total DNA and the methods used
to clone the PCR products and perform a sequence analysis of randomly
selected rDNA clones have been described previously (15).
Phylogenetic placement.
The phylogenetic analysis (i.e.,
data processing and construction of trees) was done by using the ARB
program package (36). The environmental rDNA sequences,
which were between 716 and 750 bp long, were added to a database
consisting of 176 complete or partial archaeal SSU rRNA sequences
(26, 30, 38). This database was part of the ARB program
package. Phylogenetic placement was done in comparison to reference
sequences for the main lines of descent within the three archaeal
kingdoms (i.e., the kingdoms Euryarchaeota and
Crenarchaeota [41] and the recently
proposed kingdom "Korarchaeota"
[3]). The overall tree topology was evaluated by
performing neighbor-joining analyses (31). The evolutionary
distances between pairs of sequences were calculated by using a
sequence stretching from position 148 through position 880 (Escherichia coli SSU rRNA numbering [7]).
To avoid possible treeing artifacts caused by nucleotide sequence
positions that are subject to multiple mutational changes and/or do not
align unambiguously, we used a 50% invariance criterion for the
inclusion of individual nucleotide sequence positions in the treeing
analyses (11, 13). The base frequencies of the alignment
positions were determined by using the complete data set consisting of
176 archaeal sequences or by using subsets of these sequences and the
appropriate tool of the ARB program package. As a result, we used 609 to 658 nucleotide sequence positions to construct phylogenies. We
generated several trees, which differed in (i) the reference sequences
used and (ii) the set of alignment positions used for tree
reconstruction. In addition, trees were constructed by using
maximum-parsimony (ARB and PHYLIP [10]) and
maximum-likelihood (ARB and fastDNAml [26]) methods.
The statistical significance levels of interior nodes were determined
by performing bootstrap analyses by the neighbor-joining method (ARB;
1,000 data resamplings). To exclude obvious chimeric rDNA primary
structures prior to the phylogenetic analysis, the terminal 300 nucleotide sequence positions of the 5' and 3' ends of the archaeal SSU
rDNA sequences recovered were used in separate treeing analyses. Such
chimeras may be produced during PCR amplification of mixed populations
of SSU rDNA sequences (22, 24, 39). These treeing analyses
were performed to avoid any misinterpretation with respect to the
natural presence of the distinct lineages detected in this study.
Overall rDNA sequence similarities were determined by using the
appropriate tool of the ARB program package. To ensure that the public
nucleotide sequence databases contained no previously published
reference sequences that were more closely related to our environmental sequences than the reference sequences used for the treeing analyses were, some representatives of the archaeal SSU rDNA clones recovered from flooded rice microcosms were compared with the complete EMBL nucleotide sequence database (30).
Preparation and fixation of rice roots for fluorescent in situ
hybridization.
Fresh rice roots obtained from 90-day-old flooded
rice microcosms were carefully washed in PBS (pH 7.2) and then fixed
for 1 h in freshly prepared 4% paraformaldehyde in PBS
(1). The fixative was removed by washing the roots with PBS.
Pieces of the root material were placed on glass slides, air dried, and dehydrated by successive 3-min incubations in 50, 80, and 100% ethanol. The dried and dehydrated root material preparations were stored at room temperature.
In situ hybridization and confocal laser scanning
microscopy.
The domain-specific oligonucleotide probe ARC915
(35) was used for in situ detection of archaea on rice
roots. The root material was hybridized with the rhodamine-labeled
oligonucleotide probe (50 ng) in 8 to 10 µl of hybridization buffer
(19.8 mM Tris, 0.2% SDS, 5 mM EDTA, 0.9 M NaCl, 30% formamide
[2]) at 46°C for 3 h. Following hybridization,
the slides were incubated in 40 ml of washing buffer (19.8 mM Tris,
0.2% SDS, 5 mM EDTA, 0.1 M NaCl) for 25 min at 48°C, rinsed in
deionized water, air dried, stained with 4'6'-diamidino-2-phenylindole
(DAPI) (27), and covered with Citifluor AF1 (Citifluor
Products, Citifluor Ltd., Canterbury, United Kingdom). The root samples
were examined with a confocal laser scanning microscope equipped with a
krypton-argon laser (model TCS NT; Leica, Heidelberg, Germany).
Nucleotide sequence accession numbers.
The sequences of
environmental archaeal rice root (ARR) SSU rDNA clones ARR2 to ARR40
obtained in this study and archaeal bulk soil (ABS) clones ABS3 to
ABS23 obtained in a previous study (15) have been deposited
in the EMBL, GenBank, and DDBJ nucleotide sequence databases under
accession no. AJ227919 through AJ227959.
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RESULTS AND DISCUSSION |
Roots obtained from flooded rice plants that were between 70 and
140 days old exhibited immediate in vitro production of CH4 when they were incubated under anoxic conditions (6, 12). In
addition, significant amounts of diether lipids, which are signature
compounds for the domain Archaea, have been detected on
isolated roots of mature rice plants (29). The present study was undertaken to identify archaea, especially methanogens, that are
associated with roots of flooded rice plants. Due to the known limitations of cultivation studies, we chose a cultivation-independent molecular approach to do this.
Phylogenetic placement of archaeal SSU rDNA clones recovered from
rice roots.
We generated two clone libraries, one from an
84-day-old microcosm and one from a 90-day-old microcosm. The nearly
complete PCR-amplified rDNA primary structures (716 to 750 nucleotide
sequence positions) of 32 randomly selected ARR gene clones were
determined. The regions examined included highly variable regions which
roughly corresponded to helices 9 to 11, 18, P23-1, and 24, 28, and
29 (37). All of the sequence types recovered grouped in the
domain Archaea. The phylogenetic analysis identified six
distinct lineages. Five of these lineages were detected in both
clone libraries. The sixth lineage contained
Methanobacterium-like sequences. Separate phylogenetic
analyses of the terminal 300-nucleotide sequence positions at the 5'
and 3' ends of the SSU rDNA clones provided no evidence that any of
these environmental sequence types was chimeric; i.e., all 32 sequences
clustered in the same distinct assemblages in the two separate treeing analyses.
Two distinct clusters, each containing five ARR gene clones, could be
assigned to known groups of methanogens. The first cluster was closely
related to Methanosarcina barkeri and Methanosarcina frisius, with similarity values greater than 97.9%. Two
representatives (clones ARR6 and ARR23) are shown in Fig.
1. The five sequences had very similar
primary structures (0 to 16 nucleotide sequence substitutions). The
second set of five sequences was closely related to the
H2-CO2-utilizing organism
Methanobacterium bryantii, as indicated by the three
representatives shown in Fig. 1 (clones ARR21, ARR25, and ARR39).
The levels of rDNA similarity between the SSU rDNA clones and the
corresponding Methanobacterium bryantii stretch were between
94.6% (clone ARR39) and 98.7% (clone ARR21). No
Methanosaeta-like sequences were detected in the clone
libraries generated from rice roots. This is in contrast to the results obtained with surrounding anoxic rice paddy soil;
Methanosaeta-like sequences have been identified as some of
the dominant phylotypes in the clone libraries generated with this soil
(15).
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FIG. 1.
Evolutionary distance dendrogram showing the positions
of environmental SSU rDNA sequences recovered from rice roots (ARR
sequences) and anoxic bulk soil (ABS sequences) from flooded rice
microcosms. The positions of sequences are shown in relation to the
positions of known members of the Euryarchaeota and
environmental sequences retrieved from peat bogs (R17
[16]) and from coastal marine environments (WHAR N and
SBAR 16 [9]). The numbers at the nodes indicate the
percentages of recovery in 1,000 bootstrap resamplings. The numbers in
parentheses indicate whether the environmental sequences were recovered
from 84-day-old flooded rice microcosms or 90-day-old flooded rice
microcosms. SSU rDNA sequences of Aquifex pyrophilus and of
members of the Crenarchaeota were used as outgroup reference
sequences. The tree topology was determined by using distance matrix
methods (calculation of the distance matrix with the Jukes-Cantor
equation [20], construction of the distance tree by
the neighbor-joining method [31]). Scale bar = 10% difference in nucleotide sequence positions.
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One of the intriguing findings of this study was that the remaining 22 ARR gene clones formed four distinct lines of descent
which were not
closely related to any known cultured member of
the
Archaea;
three of these lines of descent are in the kingdom
Euryarchaeota (rice clusters I to III) (Fig.
1), and one is
in
the kingdom
Crenarchaeota (rice cluster IV) (Fig.
2).
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FIG. 2.
Evolutionary distance dendrogram showing the positions
of environmental SSU rDNA sequences recovered from rice roots (ARR
sequences) and anoxic bulk soil (ABS sequences) from flooded rice
microcosms. The positions of sequences are shown in relation to the
positions of known members of the Crenarchaeota and
environmental sequences retrieved from coastal marine environments
(ANTARCTIC 12, SBAR5, and WHAR Q [9]), from a hot
spring in the Yellowstone National Park (pJP27, pJP41, pJP78, and pJP
89 [4], as well as pSL12, pSL17, and pSL22
[3]), from shallow-sediment and marsh environments
(pGrfC26 and pGrfA4 [17]), and from a forest soil
(FFSB2 [21]). The numbers in parentheses indicate
whether the environmental sequences were recovered from 84-day-old
flooded rice microcosms or 90-day-old flooded rice microcosms. SSU rDNA
sequences from Aquifex pyrophilus, from members of the
Euryarchaeota, and from members of the
"Korarchaeota" were used as outgroup reference
sequences. The dendrogram was constructed as described in the legend to
Fig. 1. Scale bar = 10% difference in nucleotide sequence
positions.
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The 14 ARR gene clones belonging to rice cluster I represented
the dominant group in the clone libraries generated from rice
root
samples. These clones formed a novel clade within the phylogenetic
radiation characterized by members of the orders
"
Methanosarcinales"
and
Methanomicrobiales,
as indicated by the six representatives
shown in Fig.
1
(clones ARR3, ARR5, ARR9, ARR14, ARR17, and ARR31).
The overall levels of rDNA similarity for the ~750-bp stretch
analyzed for sequence types belonging to this novel lineage compared
to
members of the "
Methanosarcinales" and the
Methanomicrobiales ranged from 73.6%
(
Methanocorpusculum parvum
[
Methanomicrobiales])
to 82.0% (
Methanosarcina
barkeri ["
Methanosarcinales"]). This
range is similar to the range of phylogenetic distances by which
members of the "
Methanosarcinales" and
Methanomicrobiales are
separated from each other. These
phylogenetic considerations follow
the taxonomic proposal of
Rouvière et al. (
30a), which, based
on comparative SSU
rRNA sequence analysis, divided the original
members of the order
Methanomicrobiales into the two orders
"
Methanosarcinales"
and
Methanomicrobiales.
The proposal of two distinct orders is
also supported by the
distribution of lipid component parts in
methanogens (
21a).
The phylogenetic coherence of these three
major lineages (i.e., rice
cluster I, the "
Methanosarcinales",
and the
Methanomicrobiales) was suggested by all of the phylogenies
constructed, regardless of the treeing algorithm and reference
sequences used. The intralineage levels of rDNA similarity were
between
90.9% (ARR9 and ARR31) and 100% (identical sequences)
(ARR14 and
ARR17). This range of similarity values may suggest
that rice
cluster I consists of different genotypes which may
colonize slightly
different microniches within the spatially and
temporally very
heterogeneous root environment. The two ARR gene
clones in rice
cluster II, ARR2 and ARR18 (Fig.
1), were closely
related to an
assemblage of environmental sequences previously
detected in bog peat
from an upland moor located in northern England
(typified by clone R17
[
16] in Fig.
1). Like rice cluster I
sequences, the
rice cluster II sequences were moderately related
to members of the
orders "
Methanosarcinales" and
Methanomicrobiales;
the levels of rDNA similarity
to members of these two orders were
between 75.8%
(
Methanocorpusculum parvum) and 81.4% (
Methanosarcina barkeri). The branching of rice clusters I and II within the
phylogenetic
radiation of the "
Methanosarcinales" and
Methanomicrobiales suggests
that these two environmental SSU
rDNA sequence clusters represent
methanogenic lines of descent.
However, considering the phylogenetic
distances to members of the
"
Methanosarcinales" and
Methanomicrobiales,
cultured archaea belonging to rice clusters I and II would have
to be
given the taxonomic status of a family or even an order.
One
consequence of this is that interpretation of process-oriented
studies
directed towards understanding methanogenic activity in
rice paddy
fields must take into account the abundance of methanogenic
groups with
hitherto unknown phenotypic
traits.
It cannot be assumed that members of rice cluster III and rice
cluster IV are methanogenic. The two nearly identical SSU rDNA
clones
belonging to rice cluster III, ARR16 and ARR19, formed
a branch
with
Thermoplasma acidophilum and environmental sequences
belonging to marine group II (clones WHAR N and SBAR16
[
9])
(Fig.
1). However, ARR16 and ARR19 were only
distantly related
to these taxa, as indicated by overall levels of rDNA
similarity
of about 76% to marine group II and 77.7% to
T. acidophilum. The
four ARR gene clones belonging to rice cluster IV
(ARR11, ARR29,
ARR35, and ARR38) formed a tight cluster of
deep-branching members
of the
Crenarchaeota closely related
to the environmental sequences
pGrfC26 (
18) (Fig.
2) and
pLAW12 (
32) (clone pLAW12 is not
shown in Fig.
2 because the
sequence information available for
this phylotype only partially
overlaps the sequence information
for the ARR clones). SSU rDNA clones
pGrfC26 and pLAW12 belong
to one of the deep-branching lineages of
nonthermophilic crenarchaeota
recently detected in soils and freshwater
lake sediments. The
close affiliation of rice cluster IV with these
environmental
sequences is reasonable considering that these
environmental sequences
were also recovered from flooded anaerobic
habitats (a marsh environment
[pGrfC26] and a freshwater lake
sediment [pLAW12]). Thus, detection
of this lineage in flooded rice
systems adds one important environment
to the list of reported natural
habitats for such crenarchaeotal
types.
Phylogenetic placement of archaeal SSU rDNA clones recovered from
anoxic rice paddy soil.
The nine ABS gene clones described here
were retrieved in the course of a parallel study (15). Six
of these clones belonged to one of the archaeal lineages detected on
rice roots; clones ABS5, ABS6, and ABS17 belonged to rice cluster I,
clone ABS23 belonged to rice cluster III (Fig. 1), and clones ABS13 and
ABS16 belonged to rice cluster IV (Fig. 2). However, three ABS gene clones (clones ABS3, ABS9, and ABS12 [Fig. 1]) formed a novel assemblage, designated rice cluster V. All of the treeing analyses placed this novel lineage in the kingdom Euryarchaeota,
although the exact branch point within this kingdom could not be
determined. Depending on the treeing algorithm, the reference
sequences, and the set of aligned nucleotide sequence positions used,
rice cluster V either formed a branch that was clearly distinct from
the other euryarchaeotal main lines of descent, as shown in Fig. 1, or
exhibited modest affiliation with either the T. acidophilum branch or the Methanococcus branch. The
ambiguity in the exact branch point might be a reflection of the rather
great phylogenetic distances which separated members of this novel
clade from representatives of the other major euryarchaeotal
lines. These distances ranged from 64.6%
(Halobacterium marismortui) to 76.8%
(Methanococcus jannaschii). Even the intralineage overall
levels of rDNA similarity were rather low (81.5% for ABS3 and ABS9,
82.5% for ABS3 and ABS12, and 83.7% for ABS9 and ABS12), indicating
that this assemblage of novel members of the Euryarchaeota
is phylogenetically rather diverse. Despite the great intralineage
phylogenetic distances, all three sequences shared a set of strong
signature nucleotides, e.g., at positions 338, 566, 799, and 856 (E. coli numbering [7]), relative to
the nucleotides at these positions in other euryarchaeotal main lines
of descent. This was especially true for the nucleotide at position
338, at which a guanosine has been previously reported by Winker and
Woese (40) to be highly indicative of members of the domain
Archaea. However, the three ABS gene clones belonging to
rice cluster V had an adenosine at this position, as do most bacterial
and eucaryal sequence types. The other nucleotides reported by Winker
and Woese (40) to be highly indicative of members of the
domain Archaea in the sequence stretch analyzed in this study were found in the three SSU rDNA gene clones belonging to rice
cluster V.
In situ detection of viable members of the Archaea on
rice roots.
There has been a great deal of evidence that there are
root-associated methanogenic archaea (6, 12, 29).
However, there has been no previous in vivo proof that archaea are
present on rice roots. Therefore, we used the domain-specific
oligonucleotide probe ARC915 (35) in a fluorescent in situ
hybridization analysis to verify that viable members of the
Archaea are present on the rhizoplane of 90-day-old
(flowering stage) rice plants. Strong autofluorescence of the root
material itself makes in situ localization of indigenous
root-associated microorganisms rather difficult. However, the use of
fluorescent in situ hybridization in combination with confocal laser
scanning microscopy overcomes this problem. Archaeal cells were
detected with a patchy distribution on older root sections (Fig.
3A) but not on root tips, root hairs, or
sites of lateral root emergence. Hybridization signals of the
rhodamine-labeled oligonucleotide probe were considered to be
specific only when simultaneous DAPI staining resulted in a
strong positive signal as well and when no or only weak background
autofluorescence was detected at 420 nm (Fig. 3B). All of the archaeal
cells had very similar, mainly coccoid morphotypes (diameter, 0.5 to
0.8 µm). The preferential detection of archaea on older root sections
is consistent with the idea that colonization occurs only in
oxygen-deficient microniches. Root tips, root hairs, and sites of
lateral root emergence are thought to be root microenvironments where
there is increased leakage of O2 into the surrounding soil.
However, the identification of only one distinct coccoid morphotype may suggest that not all of the archaeal subgroups detected by the molecular retrieval approach could be detected by the in situ detection
method. One reason for this could be that the standard fixation
protocols used might not be suitable for all of the different cell wall
types of members of the Archaea. Nevertheless, the in situ
survey proved that viable members of the Archaea
were present on rice roots. This conclusion was supported by the
independent recovery of archaeal SSU rDNA sequences from root material
from two different flooded rice microcosms, even though the two root batches had been processed differently prior to the extraction of total
DNA. Larger archaeal microcolonies were not detected in this survey.
However, increases from the flowering stage (~90 days) to the
ripening stage (~140 days) have been reported for both (i) in vitro
production of methane from isolated roots under anoxic incubation
conditions (6) and (ii) the levels of diether lipids
detected on roots of rice plants grown in paddy fields in the
Philippines (29). Thus, increases in root age might be paralleled by increases in the population of methanogens and increases in colonization density on the root surface.
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FIG. 3.
In situ detection of indigenous archaea on rice roots
with rhodamine-labeled domain-specific oligonucleotide probe ARC915
(35). (A) The red dots in the center are coccoid archaeal
cells that were 0.5 to 0.8 µm in diameter and specifically hybridized
with probe ARC915. The photograph is an overlay resulting from three
individual examinations, in situ hybridization with ARC915, DAPI
staining, and autofluorescence of the plant tissue. The specificities
of the hybridization signals were verified by measuring the relative
signal intensities obtained from the oligonucleotide probe signal, the
DAPI signal, and the autofluorescence signal, as shown for one optical
cut in panel B (indicated by the arrow in panel A). The root cells are
blue-green due to autofluorescence, and the dark areas correspond to
the iron precipitates which often cover rice roots. The maximum
distance between the archaeal cells and the root tissue was less than
12 µm, as determined by a z-series of optical sections, each 0.3 µm
thick. Scale bar = 5 µm. (B) The three curves indicate the
intensity of the oligonucleotide probe hybridization signal (red) in
relation to the signal intensities of DAPI staining (blue) and
autofluorescence of the plant tissue (green) for one optical cut with a
high signal/noise ratio. The signal intensities were quantified by
using the appropriate quantifying tools of the confocal laser scanning
microscope.
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The relative proportions of
Methanosaeta-like
sequences and rice cluster I sequences were different in the
archaeal rDNA clone
libraries generated from rice roots and the
clone libraries generated
from the surrounding bulk soil
(
15). This provides preliminary
evidence that there are in
vivo differences in the archaeal community
structure between these two
environments but cannot be considered
experimental proof due to
possible biases in each of the steps
of the molecular retrieval
approach (i.e., extraction of total
DNA, PCR-based amplification, and
cloning). The fact that the
root environment selects for an archaeal
community that has a
different structure than the community in the bulk
soil apparently
is probably due to the different physicochemical
properties of
the two habitats. However, the extent of the differences
can be
elucidated only by a very thorough study that takes into account
the spatial and temporal heterogeneity of the root environment.
Nevertheless, our molecular phylogenetic approach revealed remarkable
archaeal diversity on rice roots and in the surrounding anoxic
bulk
soil, and two of the lineages detected (rice clusters I and
V) were
novel. Thus, this study provided unexpected insight into
the great
naturally occurring microbial diversity which until
now has been only
partially
explored.
| |
ACKNOWLEDGMENTS |
We thank Sonja Fleissner for excellent technical assistance.
This study was supported by grants from the Deutsche
Forschungsgemeinschaft and from the Bundesministerium für
Bildung, Wissenschaft, Forschung und Technologie (contract 0311121)
awarded to W.L.
| |
FOOTNOTES |
*
Corresponding author. Mailing address:
Max-Planck-Institut für terrestrische Mikrobiologie,
Karl-von-Frisch-Straße, D-35043 Marburg, Germany. Phone: 49 (6421) 178 720. Fax: 49 (6421) 178 809. E-mail:
liesack{at}mailer.uni-marburg.de.
| |
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Abstract
Introduction
