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Applied and Environmental Microbiology, October 1998, p. 4035-4039, Vol. 64, No. 10
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Spatial Physiological Heterogeneity in
Pseudomonas aeruginosa Biofilm Is Determined by Oxygen
Availability
Karen D.
Xu,1,2
Philip S.
Stewart,1,3,*
Fuhu
Xia,1
Ching-Tsan
Huang,1,
and
Gordon
A.
McFeters1,2
Center for Biofilm
Engineering,1
Department of
Microbiology,2 and
Department of
Chemical Engineering,3 Montana State
University
Bozeman, Bozeman, Montana 59717-3980
Received 23 March 1998/Accepted 20 July 1998
 |
ABSTRACT |
The role of oxygen availability in determining the local
physiological activity of Pseudomonas aeruginosa growing in
biofilms was investigated. Biofilms grown in an ambient-air environment expressed approximately 1/15th the alkaline phosphatase specific activity of planktonic bacteria subjected to the same phosphate limitation treatment. Biofilms grown in a gaseous environment of pure
oxygen exhibited 1.9 times the amount of alkaline phosphatase specific
activity of air-grown biofilms, whereas biofilms grown in an
environment in which the air was replaced with pure nitrogen prior to
the inducing treatment did not develop alkaline phosphatase activity. Frozen cross sections of biofilms stained for alkaline phosphatase activity with a fluorogenic stain demonstrated that alkaline phosphatase activity was concentrated in distinct bands adjacent to the gaseous interfaces. These bands were approximately 30 µm thick with biofilms grown in air, 2 µm thick with biofilms grown
in pure nitrogen, and 46 µm thick with biofilms grown in pure oxygen.
Overall biofilm thickness ranged from approximately 117 to
approximately 151 µm. Measurements with an oxygen microelectrode indicated that oxygen was depleted locally within the biofilm and that
the oxygen-replete zone was of a dimension similar to that of the
biologically active zone, as indicated by alkaline phosphatase
induction. These experiments revealed marked spatial physiological
heterogeneity within P. aeruginosa biofilms in which active
protein synthesis was restricted by oxygen availability to the upper 30 µm of the biofilm. Such physiological heterogeneity has
implications for microbial ecology and for understanding the reduced
susceptibilities of biofilms to antimicrobial agents.
| |
INTRODUCTION |
It is now generally accepted that
bacteria have a marked tendency to attach to surfaces and initiate
biofilm formation (8, 13). Biofilms lead to many undesired
problems in industry, such as decreased heat transfer in cooling
towers, regrowth in drinking water distribution systems, and
deterioration of materials. In the medical area, biofilms are
responsible for dental plaque and persistent infections on medical
implants. It has long been observed that biofilms are much less
susceptible to antimicrobial agents than are their planktonic
counterparts (4, 7, 20, 25), but the underlying basis for
this recalcitrance is not well established. One of the primary
mechanisms suggested by many researchers is transport limitation of the
antimicrobial agents into the biofilm community. This mechanism is
related to the reaction or sorption of the antimicrobial agent within
the biofilm, which establishes a diffusion barrier (6, 16,
18). However, transport limitation might not be sufficient to
completely explain biofilm recalcitrance. Nichols (24)
developed a mathematical model of the penetration of two antibiotics
(the aminoglycoside tobramycin and the 
-lactam compound cefsulodin)
into biofilms of Pseudomonas aeruginosa and concluded that
transport limitation did not adequately explain biofilm resistance to
these antibiotics. Stewart (27) recently argued that, for
most antibiotics, transport limitation was insufficient to explain the
reduced susceptibilities of biofilms. Therefore, the roles of
attachment-induced responses and physiological adaptation to nutrient
limitation of bacteria in biofilms are receiving more attention
(1, 14). Specifically, it has been speculated that the
internal portions of biofilms experience starvation and slow growth due
to nutrient limitation.
Several recent papers have examined the relationship between biofilm
growth and susceptibility (2, 3, 11, 12). Growth rate
limitation occurs in biofilms presumably as a result of restriction for
a particular nutrient that fails to fully penetrate the biofilm. For
example, Tresse et al. (28) reported that oxygen limitation contributed to enhanced antibiotic resistance of agar-entrapped Escherichia coli. Oxygen concentration gradients in biofilms
have been experimentally demonstrated many times by microelectrode technology (10).
The spatial heterogeneity of growth within a biofilm is a crucial issue
in determining susceptibility to growth rate-dependent antimicrobial
agents. The purpose of the work reported in this article was to
test the dual hypotheses that physiological status varies spatially
within the biofilm and that, for a P. aeruginosa model
biofilm, physiological activity is controlled by oxygen availability. As a physiological indicator, we have used the expression of alkaline phosphatase (APase) upon exposure to phosphate
starvation, which reflects the capacity for de novo protein synthesis.
Oxygen delivery was controlled by varying the composition of the
gaseous environment and measured directly with an oxygen
microelectrode.
| |
MATERIALS AND METHODS |
Bacterial strains, media, and growth conditions.
A pure
culture of P. aeruginosa ERC1 was used throughout. It was
isolated from an industrial water system, identified with API NFT
(bioMérieux Vitek, Inc., Hazelwood, Mo.), and retained in the
culture collection of the Center for Biofilm Engineering. The 16S
ribosomal DNA of the isolate was PCR amplified with 27F (sequence,
5'-AGA GTT TGA TCC TGG CTC AG-3', which corresponds to E. coli 16S rRNA positions 8 to 27) as a forward primer and 1392R
(sequence, 5'-ACG GGC GGT GTG TAC-3', which corresponds to E. coli 16S rRNA positions 1392 to 1406) as a reverse primer and
commercially sequenced at the University of Montana (Missoula, Mont.).
When the sequence was aligned with the most similar Ribosomal Database
Project (21) sequence with Genetic Data Environment, version
2.3, software, the percent similarity between P. aeruginosa NIH18 and ERC1 was 99.0%. MOPS
(morpholinopropanesulfonic acid) minimal medium prepared as described
by Neidhardt et al. (23) was used in both planktonic and
biofilm experiments. High-phosphate medium contained 1 g of
Na2HPO4 per liter, while low-phosphate medium
contained 0.01 g of Na2HPO4 per liter.
Glucose (1.0 g/liter of the planktonic culture medium and 0.1 g/liter
of the biofilm culture medium) was used as the sole carbon source. All
the experiments were carried out at room temperature, i.e., 22.2 ± 3.0°C.
Planktonic culture procedure.
P. aeruginosa
overnight cultures were harvested by centrifugation at 7,500 rpm with a
rotor 55-34, model RC5C centrifuge (Sorvall, Inc., Oklahoma City,
Okla.) for 10 min, washed twice with low-phosphate medium, and
resuspended in 100 ml of low-phosphate medium to induce phosphate
starvation. The low-phosphate culture was stirred for 24 h.
Two-milliliter aliquots were withdrawn every hour for APase and total
protein assays. To test the effect of anoxic conditions on APase
production, a low-phosphate culture was left in ambient air for
2.5 h, connected to pure nitrogen through a bacterial air vent for
3 h, and then changed back to ambient air for another 2.5 h.
Two-milliliter aliquots were withdrawn every 30 min.
Biofilm culture procedure.
A drip-flow plate reactor was
designed to cultivate biofilms (Fig. 1).
Stainless steel slides in petri dishes were continuously bathed with
medium that dripped onto the biofilm at a constant flow rate of 50 ml/h. After inoculation with an overnight culture (3 × 108 cells/ml in 0.1 g of glucose MOPS medium/liter)
and incubation for 24 h, the reactor was fed for another 72 h
with high-phosphate medium, which was then replaced with low-phosphate
medium. The bacterial air vent of the reactor was either (i) connected
to pure nitrogen (120 to 130 ml/min) or pure oxygen (120 to 130 ml/min) or (ii) exposed to ambient air to create different gaseous
environments.
APase activity and total protein assay.
In planktonic
experiments, 2-ml aliquots were sampled, centrifuged, and then
resuspended in 1 ml of TEP solution (10 mM Tris-Cl [pH 8.0], 1 mM
EDTA [pH 8.0], 1 mM phenylmethylsulfonyl fluoride). In biofilm
experiments, attached cells were scraped into 20 ml of
phosphate-buffered saline buffer with a rubber policeman. After being treated with a homogenizer (Tissuemizer, type SDT 1810; Tekmar
Co., Cincinnati, Ohio) with an output speed of 13,500 rpm in an ice
bath for 3 min, 2-ml aliquots were suspended in 1 ml of TEP solution.
Bacterial suspensions in TEP solution were disrupted by ultrasonic
treatment with an ultrasonic cell disrupter (TORBEO, 36810 series;
Cole-Parmer, Vernon Hills, Ill.) and then centrifuged. The supernatant
was used for enzyme and total protein assays. APase activity was
determined by the rate of hydrolysis of p-nitrophenyl phosphate to p-nitrophenol, measured by absorbance at 410 nm. The changes in colorimetric intensities were monitored over a 4-min
interval. Total protein was determined with Sigma (St. Louis, Mo.)
diagnostic kit no. 690, which uses a modified micro-Lowry method.
Staining procedures.
ELF-97 phosphatase substrate (Molecular
Probes, Eugene, Oreg.) is a water-soluble faintly blue fluorescent
stain. Upon cleavage by APase, the substrate yields a bright
yellow-green intracellular fluorescent precipitate that exhibits
excellent photostability, since photobleaching is insignificant.
Therefore, bacterial cells with and without APase can be simultaneously
visualized as yellow-green and blue fluorescence, respectively, by
epifluorescence microscopy. The biofilms were stained ex situ in a
homemade staining box with 5 ml of staining solution at 35°C for 45 min. For visual microscopic examination and photography, frozen biofilm
sections were counterstained with 5 µl of 10-µg/ml propidium iodide
to improve the contrast of APase-positive and -negative cells. After
propidium iodide counterstaining, cells with APase activity exhibited
yellow-green fluorescence while cells without APase activity were red
through a U filter. For image analysis, biofilm sections were
counterstained with 5 µl of 1-µg/liter tetramethylrhodamine.
Cryoembedding and cryosectioning.
Biofilm samples were
cryoembedded with Tissue-Tek O.C.T. compound (Miles Inc., Elkhart,
Ind.) as described previously (31). Embedded samples were
sectioned with a model CM 1800 cryostat (Leica Inc., Deerfield, Ill.).
The 5-µm-thick sections were mounted on Superfrost Plus microscopic
slides (Fisher Scientific, Pittsburgh, Pa.).
Microscopy.
An Olympus (Lake Success, N.Y.) BH-2 microscope
with epifluorescence illumination was used for the examination of the
biofilm sections. After enzyme-labeled-fluorescence staining, faintly blue and intensely yellow-green fluorescence was visualized with an
Olympus U filter cubic unit containing an excitation filter (wavelength, 334 to 365 nm), a dichroic mirror (model DM-400), and a
barrier filter (model L-420).
Image analysis.
After being counterstained with
tetramethylrhodamine, cells containing APase activity (green) and all
cells (red) were selectively captured with an Olympus U and G filter
cubic unit, respectively. The G filter cubic unit contained an
excitation filter (model BP-545), a diachronic mirror (model DM-570),
and a barrier filter (model O-590). The images captured at the same
spot by different filters were digitalized by a cooled color
charge-coupled device camera (Optronics, Goleta, Calif.) and saved as
8-bit gray-scale TIFF files. The fluorescence intensity was determined
by MARK image analysis software (15).
Dissolved-oxygen profile measurement.
Oxygen profiles were
measured with a Clark-type dissolved-oxygen microelectrode equipped
with a guard cathode. The electrode was constructed as described by
Revsbech (26). Microelectrode measurements were conducted
with a micromanipulator (model M3301L; World Precision Instruments, New
Haven, Conn.) equipped with a stepper motor (model 18503; Oriel,
Stratford, Conn.). Custom data acquisition software was used to control
the microelectrode movement. The microelectrode was introduced into a
biofilm from the top, perpendicular to the substratum of stainless
steel slides. Data was collected at 10-µm increments and 2-s
intervals. Current produced by the electrode was collected and
converted to oxygen concentration by the software.
| |
RESULTS |
Planktonic and biofilm APase specific activity.
APase activity
was below detectable levels in bacteria grown in planktonic suspensions
in high-phosphate medium. After we induced phosphate starvation by
transferring the culture to low-phosphate medium, APase was readily
measured in planktonic bacteria. APase specific activity kept
increasing during the first 8 h of phosphate starvation (Fig.
2). When pure nitrogen was introduced
after a 2.5-h induction in air, APase production was immediately
arrested. Accumulation of enzyme activity resumed immediately after the nitrogen was changed back to air (Fig. 2). When bacterial biofilm was
subjected to the same duration of exposure to low-phosphate medium
under ambient aerobic conditions, the level of APase specific activity
was approximately 1/15th that of comparable planktonic bacteria (Table
1). Biofilm induction of APase was
totally blocked when pure nitrogen was administered during the
induction period, whereas induction of APase increased approximately
twofold when pure oxygen was administered (Table 1).
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FIG. 2.
APase specific activity of planktonic P. aeruginosa in response to phosphate starvation. APase specific
activity is expressed as the change in the A410
mg of protein 1 min1.  , APase specific
activity under ambient air without disruption for 8 h;  , APase
specific activity of a culture exposed to air, and then pure nitrogen,
and finally air again.
|
|
Patterns of APase expression in biofilms.
Staining with a
fluorogenic phosphatase substrate revealed a distinct, spatially
nonuniform pattern of APase expression within P. aeruginosa biofilm after induction by switching to low-phosphate medium. A control biofilm grown continuously with high-phosphate medium
showed no APase activity (Fig. 3A). APase
was expressed in a sharply delineated band adjacent to the biofilm-bulk
fluid interface (Fig. 3B). Biofilm subjected to low-phosphate medium in
a nitrogen atmosphere exhibited no visible phosphatase activity (image not shown). Conversely, when the reactor atmosphere was pure oxygen, not only was the zone of APase expression expanded but
also localized sites of APase activity could be found much deeper
inside the biofilm (image not shown).
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FIG. 3.
Photomicrographs of P. aeruginosa
biofilm cross sections stained for APase activity under different
conditions, namely, high-phosphate medium with an ambient aerobic
atmosphere (control) (A) and low-phosphate medium with an ambient
aerobic atmosphere (B). The green-yellow color represents
APase-positive cells, and the red color represents all cells. The
images are oriented with the substrata at the bottoms of the pictures.
Bar, 100 µm.
|
|
Image analysis was applied to images like those in Fig.
3 to quantitate
the dimensions of the zones of APase expression under
different gaseous
environments. A representative image analysis
result, showing a profile
for phosphatase activity along with
a profile for the entire biofilm,
is shown in Fig.
4. The mean
thicknesses
of biofilms ranged from 117 to 151 µm (Table
2).
The mean dimension of APase activity
bands was approximately 30
µm when biofilms were grown in air. With a
pure-oxygen environment,
the zone of APase activity was expanded
approximately 1.5-fold
(Table
2).
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FIG. 4.
Representative image analysis result of APase expression
in P. aeruginosa biofilms with phosphate starvation
under ambient aerobic condition.  , biofilm cells stained with
tetramethylrhodamine; , APase-positive cells.
|
|
Dissolved-oxygen measurement.
We measured the
dissolved-oxygen profile within a biofilm under ambient
aerobic conditions and superimposed image analysis data of APase
activity with the dissolved-oxygen concentration profile (Fig.
5). The dissolved-oxygen concentration
decreased from approximately 0.25 mg/liter at the biofilm-bulk fluid
interface to essentially 0 (less than 0.01 mg/liter) at a point
approximately 40 µm above the substratum. The band of APase
expression in the upper region of the biofilm coincided with
dissolved-oxygen concentrations of greater than 0.05 mg/liter.
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FIG. 5.
Correlation of the dissolved-oxygen profile with the
image analysis result of APase expression under aerobic conditions.
, APase activity; , dissolved oxygen; --, trend
line representing dissolved-oxygen concentration.
|
|
| |
DISCUSSION |
APase was first discovered in P. aeruginosa by Hou
et al. in 1966 (17). In E. coli it is induced
under the control of a complex regulatory circuit and functions in
scavenging phosphate from organic phosphate esters (22).
APase is also easily detectable in planktonic suspensions of
P. aeruginosa. In P. aeruginosa biofilms, the enzyme-labeled-fluorescence
technique coupled with cryoembedding and cryosectioning enabled
the visualization of the spatial pattern of APase
expression (19). The pattern is distinct in P. aeruginosa biofilms in an atmosphere of ambient air. We
hypothesized that this pattern is due to oxygen limitation because (i)
oxygen is often limiting in aerobic biofilms because of its rapid
consumption; (ii) in the drip-flow system, both nutrients and oxygen
come from the top of the biofilm and cells near the bulk fluid-biofilm
interface have greater access to oxygen and can consume it; (iii)
oxygen is limiting deep within biofilms as suggested by de Beer et al. (10); and (iv) enzyme biosynthesis requires both nutrients
and oxygen, since P. aeruginosa is an obligate aerobe
under the experiment conditions used (no nitrate available).
To test this hypothesis we designed a simple experiment using
planktonic bacteria to see if we could switch APase production off and
on by switching from anaerobic to aerobic conditions. The result shown
in Fig. 2 supported our hypothesis. Pure nitrogen stopped APase
production immediately, and APase production was resumed when the
biofilm was exposed to air. We then exposed biofilms to different
gaseous environments to see how the pattern of APase production would
change in the attached population. With pure nitrogen, the
expression of APase was totally blocked. This result showed that
enzyme synthesis within the P. aeruginosa biofilm required oxygen. The experiment with a pure-oxygen environment led to a
very interesting observation. The dimension of the band of APase
expression increased 1.5-fold as measured by image analysis. Also,
disperse green crystals, indicating isolated sites of APase activity,
were found deep within the biofilm. Collective APase specific activity
of the entire biofilm under ambient aerobic conditions was
approximately 1/15 of that of comparable planktonic bacteria, which
makes sense because only the upper 1/5 to 1/4 of the layer of the
biofilm was expressing the enzyme. Also, 1.0 g of glucose per
liter was used in planktonic culture to achieve enough cell mass. APase
production of the whole biofilm was increased twofold under pure
oxygen. This result supports our speculation that oxygen can penetrate
deeper within the biofilm when pure oxygen is used, but the
physiological heterogeneity of the community with oxygen-starved cells
deep within a biofilm might lead to a different response. Hence, it was
of interest to measure the penetration of dissolved oxygen. A good
correlation was observed between the oxygen penetration profile, when
the oxygen was measured under ambient aerobic conditions, and the
band of APase expression. These findings also correspond
somewhat to studies of microbial mats where changes in guild
activity reflect changing chemical composition with increasing depth in
the community (5, 9, 29).
The spatial patterns of expression of the phosphate starvation gene
that we obtained in biofilms are distinct because we chose P. aeruginosa, which is an obligate aerobe, as our
test microorganism to study the role of oxygen limitation in the
expression of the phosphate starvation response. These results may also
be related to the reduced susceptibilities of bacterial biofilms to
antimicrobial agents. Specifically, it may be important to determine
the role of limiting nutrients in the establishment of physiological
gradients to understand mechanisms of recalcitrance. Since the
spatial physiological patterns of biofilms of different
microorganisms may not be the same as those of pure P. aeruginosa biofilms (19), that goal is further
complicated in natural biofilm communities composed of both aerobes and
anaerobes. However, the results reported here for P. aeruginosa biofilms give a representative picture and support the
concept of physiological heterogeneity within biofilms (19, 30).
| |
ACKNOWLEDGMENTS |
This work was supported through cooperative agreement
EEC-8907039 between the National Science Foundation and Montana
State University and by the industrial associates of the Center for Biofilm Engineering.
We thank Betsey Pitts (Center for Biofilm Engineering, Montana State
University, Bozeman, Mont.) for PCR amplifying the 16S ribosomal DNA of
the isolate and Mary Bateson (Department of Microbiology, Montana State
University) for assistance with the phylogenetic analysis.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Chemical Engineering, Montana State University, Bozeman, MT 59717-3980. Phone: (406) 994-2890. Fax: (406) 994-6098. E-mail:
phil_s{at}erc.montana.edu.
Present address: Department of Agricultural Chemistry, National
Taiwan University, Taipei, Taiwan, Republic of China.
| |
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Applied and Environmental Microbiology, October 1998, p. 4035-4039, Vol. 64, No. 10
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
