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Previous Article | Next Article 
Applied and Environmental Microbiology, August 2000, p. 3566-3573, Vol. 66, No. 8
Department of
Microbiology1 and Center for Biofilm
Engineering,2 Montana State University, Bozeman,
Montana 59717, Molecular Probes, Inc., Eugene, Oregon
97402,3 and School of Biological
Sciences, The Flinders University of South Australia, Adelaide,
South Australia 5001, Australia4
Received 30 December 1999/Accepted 4 May 2000
The ability of marine bacteria to adhere to detrital particulate
organic matter and rapidly switch on metabolic genes in an effort to
reproduce is an important response for bacterial survival in the
pelagic marine environment. The goal of this investigation was to
evaluate the relationship between chitinolytic gene expression and
extracellular chitinase activity in individual cells of the marine
bacterium Pseudoalteromonas sp. strain S91 attached to solid chitin. A green fluorescent protein reporter gene under the
control of the chiA promoter was used to evaluate
chiA gene expression, and a precipitating enzyme-linked
fluorescent probe, ELF-97-N-acetyl- Detrital particulate organic matter
(POM) in the pelagic marine environment harbors dense microbial
assemblages (1). Bacteria associated with POM synthesize
ectohydrolytic enzymes to convert insoluble substrates into bacterial
biomass. Release of dissolved organic matter (DOM) during
ectohydrolytic enzyme degradation of POM is thought to support
bacterial production of free-living bacterial populations in the
pelagic marine environment (21, 32, 33, 40). This process
has been referred to as "sloppy feeding" by POM-associated
bacteria. However, due to methodological difficulties, bacterial
colonization and enzymatic degradation of POM are difficult to directly
observe on these surfaces.
Natural particle surfaces in the marine environment, such as chitin,
possess properties that preclude the nondestructive visualization of
single cells over time. Chitin is an insoluble homopolymer of
It was the goal of this research to overcome the obstacles associated
with natural chitin surfaces by using thin films of pure, spun-cast
chitin to visualize attached bacteria during chitin degradation. In
addition, a new precipitating enzyme-linked fluorescent (ELF-97) probe
was employed to relate chitinase gene expression to extracellular
chitinase activity in individual cells of a bacterial population during
the degradation of chitin thin films. The new enzyme substrate,
ELF-97-N-acetyl- Bacterial strains.
A GFP reporter gene (gfp) was
used to visualize chitinase gene expression of
Pseudoalteromonas sp. strain S91, during the degradation of
solid chitin. Strain S91 was derived from the wild-type strain S9, a
chitinolytic marine bacterium isolated from the surface waters of
Botany Bay, New South Wales, Australia, in 1981 (22). Strain
S91 is streptomycin (SM) resistant and contains the plasmid pDSK519,
which confers kanamycin (KM) resistance. The gene for gfp is
under the control of the chiA promoter on the plasmid, and a
fully functional chiA gene is present on the chromosome (35, 37, 40). The expression of this gene is essential for utilization of high-molecular-weight chitin as a carbon, nitrogen, and
energy source (39). The gfp gene is the GFPmut2
derivative of the wild-type gene and confers a 30-fold increase in GFP
fluorescence intensity (13).
Bacterial cultivation.
Stock cultures of S91 were grown to
exponential phase in MB2216 (Difco, Detroit, Mich.). Approximately 5 µl of this culture was used to inoculate 50 ml of a defined seawater
medium. A defined seawater medium consisted of a defined seawater
solution to which a specific carbon, nitrogen, and energy source was
added to support growth. Defined seawater solution consisted of 402.1 mM NaCl, 4.8 mM H3BO4, 27.5 mM
Na2SO4, 2.4 mM NaHCO3, 88.5 mM KCl,
8.4 mM KBr, 54.1 mM MgCl2 · 6H2O, and
1.5 mM SrCl2 · 6H2O suspended in 0.05 M
Sigma 7-9 buffer using once-distilled Millipore water and adjusted to
pH 8.0. Following autoclave sterilization, 0.008 mM FeCl3,
0.04 mM K2HPO4, and 2.0 mM CaCl2
were each added separately by filter sterilization through a
0.2-µm-pore-size Millipore syringe filter. To ensure retention of the
plasmid by the bacterial cells during cultivation, KM was added to all
culture media at a final concentration of 600 µg ml
0099-2240/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Differentiation of Chitinase-Active and
Non-Chitinase-Active Subpopulations of a Marine Bacterium during
Chitin Degradation
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-D-glucosaminide, was used
to evaluate extracellular chitinase activity among cells in the
bacterial population. Evaluation of chiA expression and
ELF-97 crystal location at the single-cell level revealed two
physiologically distinct subpopulations of S91 on the chitin surface:
one that was chitinase active and remained associated with the surface
and another that was non-chitinase active and released daughter cells
into the bulk aqueous phase. It is hypothesized that the
surface-associated, non-chitinase-active population is utilizing chitin
degradation products that were released by the adjacent
chitinase-active population for cell replication and dissemination into
the bulk aqueous phase.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-1,4-linked N-acetyl--D-glucosamine and
occurs commonly as an exoskeletal and endoskeletal material in many
marine organisms including Mollusca, Coelenterata, Protozoa, Fungi, and
Crustacea (12, 20, 28). As a result, chitin is a dominant
form of particulate carbon, nitrogen, and energy in the pelagic marine environment (27). Bacteria are the principal mediators of
chitin degradation, and their ability to promote extracellular
hydrolysis of chitin is an essential step in recycling carbon and other
nutrients in the pelagic marine environment (34).
Unfortunately, chitin displays surface roughness that generally
prevents the visualization of single cells on the surface. In addition,
chitin fluoresces under epi-illumination, preventing the use of
fluorogenic compounds that are used to visualize individual cells. Due
to the difficulty in overcoming these properties of chitin, the dynamic
relationship between the production of bacterial biomass and chitin
hydrolysis has been evaluated only at the population or community
level, and never at the single-cell level.
-D-glucosaminide, is soluble in aqueous solutions, membrane impermeable, and nonfluorescent until
cleaved by extracellular chitinase. The resulting fluorophore crystallizes at the site of enzyme action and is used in conjunction with a green fluorescent protein (GFP) reporter of chitinase gene expression. The combination of the chitin thin films, the precipitating enzyme substrate, and the reporter gene construct permitted the direct
observation of chitinase gene expression and the activity of the
chitinase gene product at the single-cell level during chitin degradation.
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
1.
-D-glucosamine (GlcNAc) was
added to the defined seawater solution as the sole carbon, nitrogen,
and energy source. Starvation cultures of S91 were first cultured on
defined seawater medium containing glutamic acid. Upon achieving a cell
density of approximately 4.2 × 107 CFU
ml1, the culture was harvested by centrifugation in a
Sorvall RC-5B centrifuge at 16,000 × g for 10 min. The
resulting cell pellet was washed three times in defined seawater
solution, and the final cell pellet was resuspended in 1.0 liter of
defined seawater solution in an air-sparged, continuously stirred tank
reactor (CSTR) at 20°C. The cells were maintained in this starvation
state for 400 h to mimic conditions that free-living bacteria
encounter in the pelagic marine environment. KM was added to the
defined seawater solution at a final concentration of 600 µg
ml1 to ensure retention of the plasmid by the bacterial
cells during starvation. SM was added to the defined seawater solution
at a final concentration of 200 µg ml1 to minimize
contamination of the cell suspension during the starvation period. The
CSTR (Knick Machining, Bozeman, Mont.) was constructed of a 1.0-liter
fluted glass reaction kettle (Lab Glass, Buena, N.J.) and a 304L
stainless steel headplate. All reactor ports were constructed of
Swagelock gas fittings with Teflon ferrules (Idaho Valve and Fitting,
Idaho Falls, Idaho).
Substratum preparation.
The physical complexity and chemical
heterogeneity found in natural detrital POM were minimized, in this
system, by using a substratum consisting of the insoluble biopolymer
chitin. Thin films of pure chitin served as the only added sources of
carbon, nitrogen, and energy during chitin degradation. Silicon
coupons, 1 cm by 1 cm square and 1.5 mm thick (Harrick Scientific,
Ossining, N.Y.), were used as nonnutritional controls. The methods used in the preparation of pure chitin thin films were adapted from previously published methods for spin-casting chitin films from chitosan solutions (5, 29, 30). Briefly, the thin films were
cast onto the silicon substrates at 4,500 rpm from a 1.5% solution of
high-molecular-weight chitosan (Aldrich, Milwaukee, Wis.) in an aqueous
solution of 2.0% acetic acid. These thin films of chitosan were N
acetylated to chitin using a 20% solution of acetic anhydride in
methanol for 18 h at 4°C. The N acetylation of the chitosan film
was monitored using Fourier transform, infrared spectroscopy, and the
chemical purity and homogeneity were assessed with small-spot X-ray
photoelectron spectroscopy (7a). Film thickness and surface
coverage were assessed using profilometry (15, 16). The
average dry density of these films was calculated to be 2.05 g
cm3 from quartz crystal microbalance mass data and
profilometry data. The exact thickness of the thin films used is
uncertain, as there was some variability that was dependent on
environmental conditions (temperature and humidity) at the time that
the films were spun-cast. However, these chitin thin films are
approximately 230 nm thick. These chitin thin films were ultrasmooth,
continuous, and nonfluorescent. These physical and chemical properties
permitted spatial quantification of attached bacteria at the
single-cell level during chitin degradation.
Laminar flow cell (LFC) preparation.
An LFC was used to
evaluate bacterial attachment, reproduction, and biofilm development on
chitin and silicon surfaces under a constant defined seawater solution
flow. Teflon LFCs with glass viewing ports were used to allow direct
microscopic examination of the surfaces without disturbing the flowing
system. Two separate LFCs were used to monitor surface-associated
bacterial activity (Fig. 1). The first
LFC contained two chitin thin films cast onto silicon coupons. The
second LFC contained clean silicon coupons and served as nonnutritional
control surfaces. The LFCs were of a design modified from that used
previously to monitor reporter gene expression on surfaces
(14). The LFCs were constructed of virgin Teflon (McMaster
Carr, Los Angeles, Calif.) and had a flow channel that was 0.8 mm deep,
12 mm wide, and 48 mm long (Knick Machining). Two 1- by 1-cm squares
were recessed, in series, into the floor of each LFC to allow the
placement of silicon or chitin coupons. A no. 2 coverslip (24 by 60 mm)
was used as the viewing window and was sealed against the Teflon using
an oversized Viton gasket and an aluminum coverplate. Teflon influent
and effluent lines were connected with Chemfluor
polytetrafluoroethylene gas fittings (Cole Palmer, Vernon Hills, Ill.).
The LFCs were connected with platinum-cured silicon tubing (Cole
Palmer) to the air-sparged CSTR and a 20-liter carboy that contained
defined seawater solution. Glass flow breaks placed in line between the
medium feed and the LFCs prevented back contamination of the sterile
defined seawater solution feed. A Buchler 12 roller Multistatic pump
(Cole Palmer) was used to transfer the starved-cell inoculum and
sterile defined seawater from their respective reservoirs to the LFCs.
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1 for 60 min, followed by
double-distilled water to remove residual organic carbon on the surface
of the tubing. Any deviation from the cleaning procedure described
above resulted in increased bacterial growth on the control surfaces.
The chitin and silicon LFCs were simultaneously inoculated with a
continuous flow of a 400-h starved-cell suspension (4.9 × 105 CFU ml1) from the CSTR over a 1-h period
at a flow rate of 0.5 ml min1. After inoculation, the
bulk aqueous phase flowing through the LFCs was switched to sterile
defined seawater solution containing KM and SM to select for plasmid
retention by cells of S91 and inhibit contamination, respectively, of
the solution reservoirs, tubing, and LFCs by other bacteria. The
sterile defined seawater solution was maintained at 20°C and pumped
through the LFCs at a constant rate of 0.5 ml min1 for a
period of 150 h. The residence time of the defined seawater solution in the flow cells was 55 s, precluding significant
replication of free-living cells in the bulk aqueous phase during the
time that it resided in the LFCs.
Total chitinase activity.
At 150 h post-inoculation of
the LFCs, chitinase activity was determined by using the fluorogenic
substrate
4-methylumbelliferyl-N-acetyl--D-glucosaminide dihydrate (MUF-GlcNAc) (Fluka no. 69585). This chitinase
substrate is soluble in water and membrane permeable and reacts
with both extracellular and periplasmic
-N-acetylhexosaminidase (chitinase) to yield the
fluorophore 4-methylumbelliferone (MUF). A stock solution of
MUF-GlcNAc was dissolved in dimethyl sulfoxide at a 100 mM
concentration. A 50 µM solution of MUF-GlcNAc was prepared by adding 500 µl of the stock solution to 1,000 ml of defined seawater solution. At 150 h postinoculation, the bulk aqueous phase flowing through the LFC was switched from sterile defined seawater solution to sterile defined seawater solution containing MUF-GlcNAc. The flow rate was maintained at 0.5 ml min1.
After 10 min, nine 2.5-ml effluent samples were collected for determination of chitinase activity contributed by surface-associated and bulk aqueous phase enzyme.
40°C during the 4-week period prior to measurement of fluorescence.
Immediately prior to measurement of sample fluorescence, each sample
was thawed and placed in a 3.5-ml optical glass cuvette (Starna Cells
Inc., Atascadero, Calif.) with a wavelength range of 320 to 2,500 nm.
The cuvette was placed in the analysis chamber of a TD-700 fluorometer
(Turner Design Inc., Sunnyvale, Calif.). A 2.5-ml volume of 50 µM
MUF-GlcNAc in defined seawater solution adjusted to pH 10.0 with
glycine-OH buffer served as a blank. The fluorescence intensity of the
samples was determined at an excitation wavelength of 360 nm and an
emission wavelength of 430 nm. MUF concentration was determined by
relating fluorescence intensity to MUF concentration using a standard
curve over the range of 0.01 to 10 µM.
Surface localization of extracellular chitinase activity.
Spatial distribution of extracellular chitinase activity, on the chitin
and silicon surfaces, was identified by using a new precipitating
fluorescent probe for -N-acetylhexosaminidase (chitinase) activity. ELF-97-N-acetyl--D-glucosaminide
(ELF-97-GlcNAc) is soluble in water and cell impermeable and reacts
with chitinase to yield the fluorophore ELF-97. This fluorophore is
insoluble in water and crystallizes at the site of enzyme action.
The methods used in the synthesis of this enzyme substrate were adapted
from previously published methods for synthesizing
ELF-97--D-glucuronide (17). Briefly,
ELF-97-GlcNAc was synthesized by oxidatively condensing
4-chloroanthranilamide with
4-chloro-2-formylphenyl-aceto--D-glucosaminide. The
resulting
4-chloro-2-[2'-(6"-chloro-4(3H)-quinazolinonyl)]-phenyl-aceto--D-glucosaminide was deprotected to yield the enzyme substrate
4-chloro-2- [2'-(6"-chloro-4(3H)-quinazolinonyl)]-phenyl--D-glucosaminide or ELF-97-GlcNAc. The enzymatic hydrolysis of this substrate
with pure Streptomyces griseus chitinase (Fluka no. 22725)
or with whole up-expressed cells of Pseudoalteromonas sp.
strain S91 yields a bright yellow-green precipitate with the excitation
(360 nm) and emission (540 nm) wavelengths of the fluorophore
2-[2'-hydroxy-5'-chlorophenyl-6-chloro-4(3H)-quinazolinone] or ELF-97
(23).
Microscopy and image analysis. At 150 h postinoculation, total cells, chiA up-expressed cells, and sites of ELF-97 activity were directly enumerated and spatially related on both the chitin and silicon surfaces. Images were acquired using an Olympus B-Max 60 microscope (Olympus Optical Co., Tokyo, Japan) employing both reflected differential interference contrast (DIC) and epifluorescence optics. All images were acquired using a Nikon infinity-corrected, 40×, water-immersion objective (Nikon Inc., Torrance, Calif.) and a mercury lamp (Chiu Technical Corporation, Kings Park, N.Y.). Digital images were gathered using a Photometrics Imagepoint cooled charge-coupled device camera (Photometrics, Tucson, Ariz.). Fluorescence images of chiA-gfp reporter gene expression were acquired using an excitation wavelength of 481 nm and an emission wavelength of 507 nm (13). Fluorescence images of ELF-97 were acquired using an excitation wavelength of 360 nm and an emission wavelength of 540 nm. All images were analyzed with Image-Pro Plus software (Media Cybernetics, Silver Spring, Md.). Image manipulation of the DIC images consisted of a background correction, adjustment of the gray-scale contrast, and one pass of a three-by-three sharpening filter. The images of gfp expression were pseudocolored green, and the images of ELF-97 activation were pseudocolored red. Total cells, chiA up-expressed cells, and sites of ELF-97 activity were counted using triple image overlays. Individual cells were counted as chitinase active if sites of ELF-97 activity were touching the cell. Four physiological states were established at the single-cell level using these image overlays: cells that were chiA down-expressed and non-chitinase active (chiA negative-chitinase negative), cells that were chiA up-expressed and non-chitinase active (chiA positive-chitinase negative), cells that were chiA up-expressed and chitinase active (chiA positive-chitinase positive), and cells that were chiA down-expressed and chitinase active (chiA negative-chitinase positive). Chitinase-active sites not associated with cells (cell negative-chitinase positive) were also located and enumerated. The software was used to count individual cells and individual sites of ELF-97 activity in all images using manually adjusted threshold values for each individual image. Four random fields were counted in each of 10 images on the chitin surface, and three random fields were counted in each of eight images on the silicon surface.
Flow cytometric analysis. A total of 17 LFC effluent samples were gathered throughout the time course of the 150-h experiment and analyzed using a Becton Dickinson FACSCalibur fluorescence-activated cell sorter. chiA expression was monitored by measuring GFP fluorescence upon excitation at 481 nm and emission at 507 nm. A maximum of 50,000 counts were acquired for each sample. Batch cultures of S91 grown on glutamic acid and GlcNAc were used as controls for chiA down- and up-expression, respectively, in cells. Detached cells were partitioned on the basis of their fluorescence intensity using ranges defined by the batch culture controls.
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RESULTS |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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chiA expression in glutamate-grown and starved cells of
S91.
gfp expression and product fluorescence reported the
level of expression of chiA, a gene involved in chitin
degradation in S91. When S91 was cultured in defined seawater medium
with glutamate as the sole added carbon, nitrogen, and energy source,
glutamate being an amino acid previously determined to support cell
growth but unable to induce detectable chitinase activity
(35), a range of levels of chiA expression from 1 to 11 relative fluorescence intensity (RFI) units was displayed by
cells in the population, based on flow cytometric analysis, a level of
chiA expression resulting in an RFI of 6 being the most
common (Fig. 2). In contrast, a
population of S91 cells grown in the presence of GlcNAc, the subunit of
chitin that is a strong inducer of chitinase activity, yielded a range
of fluorescence intensities from 1 to 1,000 RFI units, the most common
RFI displayed being 140 RFI units (Fig. 2).
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Surface colonization.
The use of thin films of the natural
biopolymer chitin permitted the assessment of chiA gene
expression in single cells attached to surfaces without interference
from the autofluorescence of natural forms of chitin. Cells that had
been starved for 400 h rapidly colonized the silicon and chitin
surfaces. Following the switch to sterile defined seawater solution,
surface-associated cells increased in size and proliferated across each
surface. DIC images of the chitin and silicon surfaces at 150 h
postinoculation revealed higher cell densities on the chitin surface
than on the silicon surface (Fig. 3A and
C). The mean cell densities ± standard errors on the chitin and
silicon surfaces were 7.6 × 106 ± 1.5 × 105 and 3.4 × 106 ± 6.4 × 104 cells cm2, respectively. These results
demonstrate that surfaces, regardless of their inherent nutritional
value, stimulate the growth of starved cells.
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Expression of chiA by surface-associated cells.
Since it was difficult to normalize the levels of fluorescence obtained
by flow cytometry and epifluorescence microscopy, up-expression of
chiA by surface-associated cells was defined in this study
as any level of fluorescence detected in a single cell by
epifluorescence microscopy. On the chitin surface, 3.2 × 106 ± 1.5 × 105 cells
cm2 or 41.5% of the total cell population was
up-expressed for chiA at 150 h postinoculation. On the
silicon surface, 1.8 × 106 ± 4.9 × 104 cells cm2 or 53.8% of the total cell
population was up-expressed for chiA at 150 h
postinoculation. Thus, a significant fraction of attached cells become
up-expressed for chiA regardless of the presence of chitin.
Chitinolytic activity of the surface-associated population. Quantification by image analysis of the area of the chitin and silicon surfaces displaying ELF-97 fluorescence allowed a comparison of chitinase activity by cells colonizing these surfaces. Of the total exposed surface area, 11.6% ± 1.5% displayed fluorescence 150 h postinoculation on the chitin surface and 2.9% ± 0.3% displayed fluorescence on the silicon surface.
Relationship between expression of chiA gene and
chitinase activity of surface-associated populations.
The combined
use of the gfp reporter for chiA gene expression
and the precipitating enzyme substrate
ELF-97-N-acetyl--D-glucosaminide permitted
the evaluation of the relationship between chitinase gene expression
and gene product activity at the single-cell level. While it was
difficult to resolve individual cells in some areas of the chitin
surface containing high cell densities, other areas of the surface
contained low-enough cell densities to resolve individual cells. These
areas of lower cell density were therefore used to evaluate phenotypic
differences among cells associated with the chitin and silicon
surfaces. Image overlays revealed chitinase activity both directly
adjacent to (Fig. 3E) and directly associated with (Fig. 3F)
chiA up-expressed cells. When chitinase activity was
observed, it was associated with chiA up-expressed cells on
both chitin and silicon surfaces (Fig. 3B and D). However, many
chiA up-expressed cells were not associated with
chitinase-active sites. Furthermore, many cells on both the chitin and
silicon surfaces exhibited no chiA activity.
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Expression of chiA by detached cells. Analysis of chiA expression by cells that were displaced from the surfaces into the effluent of the LFCs was determined by flow cytometry. Cells that detached from either the chitin or the silicon surface displayed comparably low levels of chiA expression relative to that of up-expressed cells grown in GlcNAc (Fig. 2). Whereas an RFI of 140 was displayed by the greatest number of cells grown in GlcNAc, an RFI of 3 was displayed by the greatest number of cells that had detached from either the chitin or the silicon surface (Fig. 2). Interestingly, the level of expression of chiA in the population of cells that detached from the chitin and silicon surfaces was comparable to that of the starved-cell population used to inoculate the LFCs (Fig. 2).
Throughout the 150-h time course of the experiment, only (0.2 ± 0.03)% (n = 17) and (0.1 ± 0.02)% (n = 17) of the total cells that detached from the chitin and silicon surfaces, respectively, displayed RFI levels of 12 or greater, the minimum RFI for a cell considered to be up-expressed for chiA. By comparison, (71.5 ± 3.4)% of the total cells in a GlcNAc-grown batch culture, (3.3 ± 0.8)% of the total cells in a glutamate-grown batch culture, and (0.8 ± 0.05)% of the total cells in the 400-h starvation culture used to inoculate the LFCs were up-expressed for chiA. Thus, the fraction of detached cells that are up-expressed for chiA is even lower than that of a starved-cell population.Distribution of chitinase activity.
To assess the distribution
of chitinase activity between the surface and bulk aqueous phase,
chitinase activity was determined with MUF-GlcNAc, a soluble,
membrane-permeable analog to the
ELF-97-N-acetyl--D-glucosaminide substrate
(Table 2). Using the same molar
concentration for MUF-GlcNAc as for
ELF-97-N-acetyl--D-glucosaminide, enzyme
activities in the effluent from the LFCs containing chitin and silicon
were 0.47 ± 0.05 and 0.24 ± 0.03 µmol
liter1 h1, respectively, when no further
incubation was carried out. When the effluent samples were incubated
for an additional 60-min period, no additional chitinase activity was
detected, suggesting that there was no significant activity contributed
by free enzyme or enzyme associated with detached, free-living
cells. Therefore, the majority of chitinase activity in this
system was surface associated. The lack of chitinase activity
among detached free-living bacteria indicates that this subpopulation
maintains the chiA-negative-chitinase-negative phenotype.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Up-expression of chiA following attachment of starved cells of S91 to chitin is consistent with other studies that have shown chitin utilization by marine bacteria to be a complex and highly regulated process (20). Bassler et al. (6, 7) have shown chitin utilization by Vibrio furnissii to be a multistep process, involving a chemotactic response and production of different enzymes that hydrolyze the various degradation products of the chitin polymer. That cells became up-expressed for chiA when attached to the silicon surface in the absence of chitin was unanticipated and suggests that expression of this gene was a surface-controlled response, independent of the inherent nutritional value of the surface. While it is now known that expression of numerous genes is controlled by cell attachment to a surface (8), little is known about those properties of the surface that are involved in the process. Yu et al. (42) showed that attachment of V. furnissii to a surface was dependent on the surface displaying glycosides containing either GlcNAc, D-mannose, or D-glucose. Cell adhesion to these sugars was mediated by a Ca2+-dependent cell surface lectin that interacted directly with these sugar subunits. Since the silicon surface contained no sugars, the mechanism of adhesion of cells of S91 is not likely to involve sugar-lectin interactions.
In addition, attachment to a surface, irrespective of the presence of chitin, promoted synthesis and excretion of active chitinase. We hypothesize that the cells produce a "sensing" amount of the enzyme to continuously monitor availability of chitin on the surface, analogous to the nutrient sensorium proposed for the adhesion-deadhesion apparatus in V. furnissii (42).
A new method for localizing extracellular chitinase activity confirmed
the presence of four subpopulations during chitin degradation: two
subpopulations (chiA positive-chitinase positive and
chiA negative-chitinase positive) that actively synthesized
and excreted extracellular chitinase enzyme and two other
subpopulations (chiA negative-chitinase negative and
chiA positive-chitinase negative) that did not produce
extracellular chitinase enzyme. The detection of
chiA-positive-chitinase-negative and
chiA-negative-chitinase-positive subpopulations was
unexpected. Cells displaying the
chiA-positive-chitinase-negative phenotype may have
recently initiated chitinase synthesis, with not enough active enzyme
excreted to convert a threshold amount of enzyme substrate to a
detectable fluorescent product. We cannot exclude the possibility that
the chiA-positive-chitinase-negative subpopulation
produced an endochitinase that may not have reacted with
ELF-97-N-acetyl--D-glucosaminide. It is
possible using the current synthesis method for
ELF-97-N-acetyl--D-glucosaminide to
synthesize the corresponding
ELF-97-N,N'-diacetyl--D-chitobioside and
-N,N',N"-triacetyl--D-chitotrioside
enzyme substrates to distinguish different chitinase enzymes. In
combination with the MUF analogs, these substrates should enable
the distinction of different chitinase activities at the
single-cell level.
Detection of the chiA-negative-chitinase-positive
phenotype, on the other hand, suggests that cells are capable of
liberating an
ELF-97-N-acetyl--D-glucosaminide-hydrolyzing
enzyme that is encoded by a gene that operates independently of the
chiA promoter. Many chitinolytic bacteria, including S91,
possess multiple chitinase genes controlled by different promoters
(24, 36, 38, 41). The small contribution made by this
phenotype to the total population of S91 cells, however, suggests
that up-expression of the chiA gene was highly
correlated with chitinase activity in the population, as reported
with ELF-97-N-acetyl--D-glucosaminide under
the conditions of this study. The small contribution of the
chiA-negative-chitinase-positive phenotype among cells of
the total surface-associated population also suggests that the
chiA promoter-gfp construct is relatively stable
in the S91 population under the conditions employed in this study, as
loss of the reporter gene would give rise to this phenotype.
The detection of such a large subpopulation that displayed the chiA-negative-chitinase-negative phenotype was also unexpected. Others have suggested that POM-associated bacteria generate more DOM from the hydrolysis of POM than they can utilize, resulting in the release of DOM into the bulk aqueous phase for utilization by free-living bacteria (3, 4, 11). It is hypothesized that, in our model system, the chiA-positive-chitinase-positive subpopulation was responsible for the generation of excess chitin hydrolysate during growth and replication on the chitin surface and that the excess hydrolysate was utilized by the chitin surface-associated chiA-negative-chitinase-negative subpopulation for growth and replication. An alternative hypothesis is that a portion of the chiA-positive-chitinase-positive subpopulation changes to the chiA-negative-chitinase-negative phenotype while associated with the surface. This may be the case when cells displaying the chiA-positive-chitinase-positive phenotype deplete their surroundings of chitin or produce adequate amounts of soluble chitin degradation products for their metabolic needs. Either of these conditions may promote down-expression of chiA, causing the cells to transiently display the chiA-negative-chitinase-positive phenotype before the extracellular chitinase produced previously by the cell is degraded or diffuses away, which would then result in a chiA-negative-chitinase-negative phenotype. Support for the alternative hypothesis therefore requires the presence of the transient chiA-negative-chitinase-positive phenotype, since conversion to the chiA-negative phenotype would not cause the precipitated, fluorescent ELF-97 product around the cell to disappear simultaneously but instead yield a chiA-negative-chitinase-positive phenotype. That this phenotype was displayed by only 1% of the total population suggests that conversion of cells from the chiA-positive-chitinase-positive to the chiA-negative-chitinase-negative phenotype was not significant among cells attached to either the chitin or the silicon surface.
The hypothesized dependence of the surface-associated chiA-negative-chitinase-negative subpopulation on chitin degradation products produced by the chiA-positive-chitinase-positive subpopulation may suggest cell-cell interaction. Intraspecies cooperation may result in more efficient utilization of the carbon, nitrogen, and energy available in chitin by the surface-associated population as a whole and allow for two energy-intensive cellular activities (chitinase production and cell replication) to occur simultaneously. Phenotypic variation within a bacterial population is generally recognized when individual traits manifest themselves through distinguishable morphological features (9). In one of the best-known examples, vegetative cells of Myxococcus xanthus aggregate and undergo morphogenesis to form fruiting bodies that differentiate into myxospores (25, 31). Likewise, as Streptomyces colonies age, cells differentiate into aerial filaments called sporophores that give rise to spores called conidia that germinate to form new vegetative cells (10). Caulobacter crescentus is known to attach to surfaces, form a stalk that serves as an adhesive holdfast, and undergo cell division that results in a flagellated swarmer cell (19, 26). In all of these examples, morphological differentiation distinguishes members of a population with different life histories that work cooperatively to enhance the survival of the population. However, unlike the above examples, differentiation among members of S91 was not manifested as a gross change in morphology. Rather, the differentiation occurred at the level of gene expression and extracellular enzyme production. Considering the possibilities of differential gene expression within any genome, it is likely that this type of phenotypic variation is more common than that which results in gross changes in morphology.
That detachment of cells was observed from both the chitin and silicon surfaces is consistent with the behavior described previously for the chitin-degrading marine bacterium V. furnissii (42). Yu et al. (42) reported that the first progeny of adherent cells of V. furnissii continued to bind to glycoside-coated beads but the population gradually shifted over six cell divisions to a large fraction of free-swimming cells that represented 80 to 90% of the total population. It was proposed that the adhesion-deadhesion apparatus is used by the bacterium to continuously monitor the nutrient status of the environment, prevent overcrowding, and permit colonization of more favorable environments.
The chiA-negative-chitinase-negative phenotype displayed by the bulk of the cells that detached from both chitin and silicon surfaces suggests that the cells that detach from these surfaces are physiologically more homogeneous than those cells remaining on the surfaces. Since the residence time of the bulk liquid in the system is less than the generation time of the bacteria, and the half-life of the non-protease-sensitive GFP used in the cells of this study is more than the 45 min to several hours reported for the less stable protease-sensitive GFP (2), the biomass associated with the chiA-negative-chitinase-negative free-living cell population must have originated from the surface-associated population of the same phenotype. In this scenario, chiA up-expressed cells still remain associated with the surface, while detached cells are derived almost exclusively from the subpopulation displaying the chiA-negative-chitinase-negative phenotype. The basis for this strong partitioning of chitinase-producing cells to remain associated with the surface and the detachment of only cells displaying the chiA-negative-chitinase-negative phenotype remains to be determined.
In summary, evaluation of microbial processes at the single-cell level may be necessary in order to resolve pathways of carbon flux in the marine environment. We have demonstrated that synthesis of extracellular chitinase enzyme, like the up-regulation of chitinase genes in surface-associated bacteria, varies among individual cells within a population exposed to apparently homogeneous environmental conditions. The ability of a population to coordinate chitinase activity, cell reproduction, and surface detachment among different cells on a surface should enhance their ability to locate new sources of nutrients in the pelagic marine environment.
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ACKNOWLEDGMENTS |
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We gratefully acknowledge Sandra Kurk at the Department of Veterinary Molecular Biology at Montana State University for her help in flow cytometric analysis. We also recognize Samuel Hudson at North Carolina State University for sharing his expertise in the preparation of chitin films.
Part of this work was supported by The Flinders University of South Australia and the Australian Research Council. Somkiet Techkarnjanaruk was supported by a Royal Thai Government Scholarship. This work was sponsored by the National Science Foundation under grant OCE 9720151 to Gill Geesey and the National Institutes of Health under grant S10RR11877 to Mark Jutila and under the National Science Foundation cooperative agreement EEC 8907039.
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FOOTNOTES |
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* Corresponding author. Mailing address: Center for Biofilm Engineering, 366 EPS Building, Montana State University, Bozeman, MT 59717. Phone: (406) 994-3820. Fax: (406) 994-6098. E-mail: gill_g{at}erc.montana.edu.
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REFERENCES |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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). The silicon and chitin
LFCs were run in tandem. Epi, epifluorescence.
