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Journal of Bacteriology, February 2001, p. 1078-1084, Vol. 183, No. 3
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.3.1078-1084.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Cytoplasmic Filament-Deficient Mutant of
Treponema denticola Has Pleiotropic Defects
Jacques
Izard,*
William A.
Samsonoff, and
Ronald J.
Limberger
Wadsworth Center, David Axelrod Institute for
Public Health, New York State Department of Health, Albany, New
York 12201-2002
Received 18 September 2000/Accepted 2 November 2000
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ABSTRACT |
In Treponema denticola, a ribbon-like structure of
cytoplasmic filaments spans the cytoplasm at all stages of the cell
division process. Insertional inactivation was used as a first step to determine the function of the cytoplasmic filaments. A suicide plasmid
was constructed that contained part of cfpA and a nonpolar erythromycin resistance cassette (ermF and
ermAM) inserted near the beginning of the gene. The plasmid
was electroporated into T. denticola, and double-crossover
recombinants which had the chromosomal copy of cfpA
insertionally inactivated were selected. Immunoblotting and electron
microscopy confirmed the lack of cytoplasmic filaments. The mutant was
further analyzed by dark-field microscopy to determine cell morphology
and by the binding of two fluorescent dyes to DNA to assess the
distribution of cellular nucleic acids. The cytoplasmic filament
protein-deficient mutant exhibited pleiotropic defects, including
highly condensed chromosomal DNA, compared to the homogeneous
distribution of the DNA throughout the cytoplasm in a wild-type cell.
Moreover, chains of cells are formed by the cytoplasmic
filament-deficient mutant, and those cells show reduced spreading in
agarose, which may be due to the abnormal cell length. The chains of
cells and the highly condensed chromosomal DNA suggest that the
cytoplasmic filaments may be involved in chromosome structure, segregation, or the cell division process in Treponema.
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INTRODUCTION |
Treponema denticola is
one of the major spirochete species associated with the periodontitis
pandemic (45). The treponemes are invasive due to their
unique motility in dense media and their ability to penetrate cell
monolayers (47). This feature is associated with their
helical or wave-shaped cell body and the periplasmic flagellar filament
location (15, 24, 40).
The cytoplasmic filaments in treponemes are persistent and span the
length of the cell (21). They are located underneath the
periplasmic flagellar bundle in close apposition to the cytoplasmic membrane (8, 18). The filaments are composed of one major protein (33) that is well conserved among species
(21), and the gene encoding them, cfpA, is
preceded by a sigma 70 promoter (21, 53). In
Treponema pallidum subsp. pallidum, the
cytoplasmic filament protein, CfpA, is Tpn83, an antigen recognized by
sera from humans with syphilis (37, 53). This cytoplasmic
structure is found in cells at all growth stages and severs during cell division (21). Proposed to be involved in cell structure,
cell motility, and cell division (8), the filamentous
nature of the structure and the location of the cytoplasmic filaments
also make them a candidate for involvement in chromosome structure or segregation.
In order to achieve a better understanding of the potential
relationship between the cytoplasmic filaments and the
chromosome, we insertionally inactivated T. denticola
cfpA. The CfpA knockout was nonlethal and did not alter cell
structure. The mutant predominantly formed chains of cells, and
the chromosomal DNA was condensed in distinct areas. We propose
that the cytoplasmic filament structure is actively involved in
chromosome structure maintenance, segregation, or cell division.
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MATERIALS AND METHODS |
Strains, reagents, culture, and molecular methods.
T.
denticola ATCC 33520 and the cytoplasmic filament-less mutant were
grown in New Oral Spirochete medium (NOS) with 10% heat-inactivated rabbit serum and 10 µg of cocarboxylase per ml at 36°C in an
anaerobic chamber (Coy Laboratory Products Inc., Grass Lake, Mich.)
with an atmosphere of 85% nitrogen, 10% carbon dioxide, and 5%
hydrogen. Oligonucleotides were synthesized by the Molecular Genetics
Core Facility of the Wadsworth Center, using PerSeptive Biosystems 8909 (PE Biosystems, Foster City, Calif.). T. denticola
chromosomal DNA and plasmid miniprep DNA were isolated by standard
methods (32). PCR was performed using Taq
polymerase, reagents, and thermal cyclers available from Perkin Elmer
(Foster City, Calif.).
Construction of a plasmid containing T. denticola
cfpA interrupted with a modified erythromycin resistance
cassette.
The partial DNA sequence of T. denticola
cfpA previously cloned in the pZero-2 vector (Invitrogen,
Carlsbad, Calif.) (21) was used as the starting point for
the construction of a suicide plasmid. The cfpA gene was
interrupted at the beginning of the gene (DraI site). The
erythromycin resistance cassette (ermF-ermAM cassette) used
for insertional inactivation of T. denticola cfpA was
described by Li and Kuramitsu (27) and was obtained by
amplification of pJS97 using primers ERMBGLF and ERMBGLR
(30). The ermF-ermAM cassette was then ligated
to the DraI-digested pZero-2 plasmid that contained T. denticola cfpA (NTPHDE1N and DENTCF2R amplification product).
Orientation of the cfpA gene and the ermF-ermAM
cassette was determined by PCR using primers DENTCF4, located in the
cfpA sequence (5'-AAATCGCTACCCTTCTTGATG-3'),
and ERMFBGLR, located in the
ermF sequence (5'-TATAAGATCTCAACCACCCGACTTTGAACTA-3'); only those
clones containing the ermF-ermAM cassette in the same
direction as cfpA were chosen for electroporation.
Nonmethylated plasmid DNA for electroporation of T. denticola was prepared in Escherichia coli SCS110
(Stratagene) using Qiagen Midi columns (Qiagen Corp., Chatsworth,
Calif.) and concentrated with Spin-X UF100 columns (Costar,
Cambridge, Mass.).
Insertional inactivation of T. denticola cfpA using
an ermF-ermAM cassette.
Based on the protocol of Li
and Kuramitsu as modified by Limberger et al. (30), 12.6 µg of nonmethylated plasmid DNA prepared in E. coli SCS110
was used to electroporate T. denticola ATCC 33520 competent
cells. Briefly, 100 ml of T. denticola was grown to an
optical density at 600 nm of 0.3. Cells were washed three times with
cold 10% glycerol in water and resuspended in a final volume of 2 ml
on ice. Electroporation was done using 1 µl of nonmethylated plasmid
DNA, at a concentration of 12.6 µg/µl, in 100 µl of cells, using
a Bio-Rad Gene Pulser at 1.8 kV, 200 
, and 25 µF and a 0.1-cm
cuvette (Bio-Rad Laboratories, Hercules, Calif.). The time constant was
4.3; time constants of 4.1 to 4.6 are optimal. After overnight
incubation in 10 ml of NOS broth without erythromycin, cells were
cultured on NOS plates with 25 µg of erythromycin per ml. Colonies
were visible after 7 days. Twenty colonies out of approximately 500 transformants were randomly selected, grown in liquid culture, and
replated to ensure no cross-contamination by DNA present in the plated
sample after electroporation. To check for the presence of the gene
that confers resistance to erythromycin in T. denticola
(ermF), a PCR was performed using primers ERMBGLF
(5'-TATAAGATCTCCGATAGCTTCCGCTATTGC-3') and ERMBGLR. To check
the relative position of the antibiotic resistance cassette in
the chromosome, four PCR assays were performed. The first one used
primers DENTCF4 and ERMBGLF. One assay used primers ERMBGLR and DENTCF5 (5'-GCAGCCAAATCGTTAAAG-3'), located outside the
cloned sequence in the pZero-2 vector in the 3' end of the
cfpA sequence. One assay used primers SP6
(5'-ATTTAGGTGACACTATAG-3'), located in the vector, and
ERMBGLR. The last assay used primers T7
(5'-TAATACGACTCACTATAGGG-3'), located in the vector, and
ERMAMF, located in ermAM sequence
(5'-CAGCGGAATGCTTTCATC-3').
Antibody production and immunoblotting.
Antiserum was raised
against purified T. phagedenis CfpA purified filaments
(21) in BALB/c mice, using RIBI adjuvant (RIBI Immunochemical Corp., Hamilton, Mont.) as described previously (31). Monoclonal antibody production was done using the
Hybridoma Generation ClonaCell-HY kit (Vancouver, BC, Canada) and the
spleen of a mouse immunized with purified T. phagedenis
cytoplasmic filaments. A mid-log-phase culture of T. denticola was spun down for 1 min at 12,000 × g.
The pellet was resuspended in 10 mM sodium phosphate (NaPi, pH 7.4)
buffer and washed twice. The pellet was then resuspended in 1 mM
EDTA-10 mM NaPi (pH 7.4) and sonicated for 1 min (Heat Systems
Ultrasonics, Farmingdale, N.Y.). The quantity of protein was evaluated
by the Bradford protein assay (Bio-Rad Laboratories). Sodium dodecyl
sulfate-polyacrylamide gel electrophoresis was done using a Daiichi
cassette electrophoresis unit and 10 to 20% Owl precast gels (Owl
Separation System, Woburn, Mass.). Five micrograms of cell extract was
loaded per lane, as well as 10-kDa protein ladders (Gibco-BRL, Grand
Island, N.Y.). Gels were transferred onto 0.45-µm nitrocellulose
membranes (Bio-Rad Laboratories) using the mini-transblot cell (Bio-Rad
Laboratories). Immunoblots were performed using standard techniques
with a monoclonal or polyclonal antibody directed against T. phagedenis CfpA and a goat anti-mouse immunoglobulin-alkaline
phosphatase conjugate secondary antibody (Bio-Rad Laboratories).
Dark-field microscopy and motility test.
One milliliter of
mid-log-phase culture was centrifuged for 1 min at 12,000 × g, and the pellet was suspended in 20 µl of reduced NOS or
phosphate-buffered saline. Two hundred microliters of 0.5%
methylcellulose (15 centipoise) was added (29). The cell
mobility was observed by dark-field microscopy using a heated stage at
36°C (Fryer Co., Inc., Huntley, Ill.). Dark-field microscopy was
performed using a Nikon Eclipse E600 microscope equipped with an oil
dark-field condenser 1.43-1.20 and a Nikon Plan Fluor x100 0.5-1.3 oil
objective. Pictures were taken with a Nikon FDX-35 camera mounted on a
Nikon H-III unit (Nikon, Inc., Melville, N.Y.).
Visualization of chromosomal DNA.
Cells were grown in NOS
broth, fixed with 1% glutaraldehyde, deposited on a
poly(L-lysine)-treated slide, the DNA-binding dye Hoechst
33342 (Molecular Probes) (10 µg/ml) was added, and the slide was
washed with water after 20 min. For fluorescence microscopy, a 100-W
mercury lamp and a UV-2E/C filter were used (Nikon). An alternative
protocol was also used. Cells were washed with 10 mM Tris-HCl (pH 7.4)
buffer and suspended in 1 ml of 70% ethanol for fixation. The fixed
cells were collected by centrifugation, washed with the same buffer,
and deposited on a poly(L-lysine)- treated slide. Cells
were stained with a DAPI (4',6'-diamidino-2-phenylindole) solution
(Molecular Probes) at 1 µg/ml in water.
Evaluation of the number of anucleated cytoplasmic
cylinders.
Three samples representative of log-phase growth were
evaluated for anucleated cytoplasmic cylinders in the wild type and the
cytoplasmic filament-less mutant. To 100 µl of sample, 1 µl of
Hoechst 33342 (10 mg/ml) was added (Molecular Probes, Inc.). After 15 min of incubation in the dark, the sample was observed by fluorescence
and dark-field microscopy. One hundred twenty-six cells were evaluated
for the presence of anucleated cytoplasmic cylinders in each of the
three sample of the wild type and the cytoplasmic filament-less mutant.
Electron microscopy.
For electron microscopic visualization
of T. denticola cells, 1 ml of logarithmio-phase culture was
centrifuged for 1 min at 10,000 × g. The pellet was
resuspended in the same amount of water with 0.5% deoxycholic acid
sodium salt (Sigma-Aldrich, St. Louis, Mo.) and stored at 4°C
overnight. The sample was centrifuged for 1 min at 10,000 × g, and the pellet was resuspended in 100 µl of sterile distilled
water prior to use. Negative staining with sodium phosphotungstate was
done as previously described (21). The samples were viewed
in a Zeiss (LEO) 910 transmission electron microscope operating at 80 keV. The negatives were enlarged photographically.
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RESULTS |
Interruption of cfpA with an erythromycin resistance
cassette.
To create a specific mutant of T. denticola
that was deficient in CfpA, a suicide plasmid was constructed that
contained an ermF-ermAM antibiotic resistance cassette
inserted within T. denticola cfpA. The ermF-ermAM
antibiotic resistance cassette does not terminate transcription or
decrease the RNA level in T. denticola (30). Electroporation-mediated allelic exchange replaced the wild-type cfpA with the interrupted cfpA construct in the
T. denticola chromosome. Several colonies out of
approximately 500 were selected for further analysis by PCR and
dark-field microscopy. Individual colonies were tested by PCR and were
indistinguishable clones that had undergone a similar double-crossover
recombination event to interrupt cfpA (data not shown).
Therefore, one clone was used for all subsequent analyses.
Immunoblotting.
Immunoblots were done to assess whether CfpA
was detectable in the cfpA-interrupted mutant. Using mouse
polyclonal sera (data not shown) or a monoclonal antibody that reacts
with T. denticola CfpA, the immunoblot revealed no trace of
CfpA protein present in T. denticola cfpA-interrupted mutant
cells (Fig. 1).
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FIG. 1.
Immunoblot using monoclonal antibody M416 against
T. phagedenis CfpA. (A) T. phagedenis
cell extract. (B) Lane 1, T. denticola cell extract;
lane 2, T. denticola cfpA mutant cell extract. The positions
of size markers are shown (in kilodaltons).
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Colony formation in agarose.
The pathogenicity of T. denticola is associated with its unique motility in dense medium,
which is mediated by the periplasmic location of the flagellar
filaments and the wave-shaped cell. After being plated on 0.5%
agarose-NOS medium, T. denticola wild-type bacteria spread
throughout the agarose (Fig. 2 and
3). No colony growth above the agarose
was observed by macroscopic methods (Fig. 2B). In contrast, a
previously described nonmotile mutant (30) formed colonies
growing above the agarose over a limited surface (Fig. 2 and 3).
T. denticola CfpA-deficient colonies spread within the
agarose in a limited volume compared to the wild type (Fig. 2 and 3).
Thus, T. denticola CfpA-deficient cells are characterized as
having an altered motility in dense medium.
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FIG. 2.
Macroscopic motility test in dense medium. (A) Plate
after 3 days of incubation. A liquid culture (0.1 µl) of each sample
was spotted on a 0.5% agarose-NOS plate and incubated at 36°C. 1, T. denticola wild type; 2, T. denticola
CfpA-deficient mutant; 3, T. denticola fliK flagellar
filament-less mutant (30). (B) T. denticola
wild-type from a 3-day plated culture spread in agarose and propagated.
Vertical section of the plate with side illumination. Bar, 1.5 mm. (C)
Plate after 7 days of incubation, same strains as in panel A. (D)
Vertical section of the plate with side illumination. Bar, 1 mm.
T. denticola CfpA-deficient mutant from a 7-day plated
culture does spread in the agarose but in a more limited volume. (E)
Vertical section of the plate with side illumination. Bar, 1 mm.
T. denticola fliK flagellar filament-less mutant from a
7-day plated culture was nonmotile and did not spread in the agarose.
The vertical section photographs of the plate with side illumination
were obtained using an SZ40 stereo microscope with a 35-mm camera
mounted on a PM-20 exposure control unit (Olympus, Melville, N.Y.).
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FIG. 3.
Macroscopic measurement of cell spreading over time in
dense medium. A liquid culture (0.1 µl) was spotted on the center of
a 0.5% agarose-NOS plate and incubated at 36°C. The colony diameter
was measured using a caliper.  , T. denticola wild-type
colony;  , T. denticola cytoplasmic filament-less mutant
colony;  , T. denticola fliK flagellar filament-less
mutant colony (30). Error bars show the range of measured
colony diameters.
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Cell morphology, chaining and motility.
Direct observation of
T. denticola wild-type and CfpA-deficient cells using
dark-field microscopy showed no morphological difference at the
single-cell level (Fig. 4A through C).
Thus, the absence of the cytoplasmic filament ribbon did not alter the morphology of a single cell; in particular, the wave shape was retained. However, in the CfpA-deficient mutant, a single cell was
rarely observed (less than 1%) at any stage of growth. A
representative cell from a culture of the CfpA-deficient mutant is
shown in Fig. 4D. The long cells are composed of several cells that
have undergone cell division but are unable to separate. Using
dark-field microscopy and a warm stage at 36°C, the motility
phenotype of the CfpA-deficient mutant was observed. The cells in the
chain were unable to move significantly compared to a single cell. The
asynchronous crankshaft-like movement of the cell chain might by itself
be the reason for the poor motility of these organisms in dense medium.
However, a rarely observed cytoplasmic filament-less single cell, like
the one shown in Fig. 4C, does not significantly differ in cell
movement from the wild-type bacteria at 36°C.
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FIG. 4.
T. denticola wild-type and CfpA-deficient
cells from a mid-log-phase NOS broth culture as observed by dark-field
microscopy. (A) Representative single cell of wild-type T. denticola. (B) Wild-type T. denticola
undergoing cell division. (C) A rarely observed single cell of T. denticola CfpA-deficient mutant. (D) Representative cell of
T. denticola CfpA-deficient mutant. Bars, 5 µm.
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Electron microscopy.
Electron microscopic analysis of the
cytoplasmic filament-deficient mutant did not reveal any obvious
structural or morphological differences compared to wild-type cells at
the cell ends. The flagellar filament and flagellar basal body are
indistinguishable from the wild type (Fig.
5), indicating that the cytoplasmic
filaments are not needed for periplasmic flagellar synthesis and
assembly despite their close association. No cytoplasmic filament was
detectable, as expected (Fig. 5). The cells are longer than the
wild-type cells, and usually several cytoplasmic cylinders can be
observed under a unique outer membrane (data not shown).
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FIG. 5.
Electron micrograph of wild-type T. denticola
(A) and cytoplasmic filament-less mutant (B) cells. The outer membrane
has been removed by detergent treatment of the cell using sodium
deoxycholate 1% for 10 min, and the periplasmic flagellar filaments
are freed. No cytoplasmic filaments were detected in the CfpA-deficient
mutant. PFF, periplasmic flagellar filament; CF, cytoplasmic filament.
Bar, 1 µM.
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Visualization of chromosomal DNA.
To investigate the
involvement of T. denticola cytoplasmic filaments in
chromosome segregation or structure, T. denticola wild-type and CfpA-deficient cells were observed after
incubation with Hoechst 33342, a fluorescent dye that binds to DNA.
There was uniform distribution of the chromosomal DNA in T. denticola wild-type cells, which filled most of the cells, as
shown in Fig. 6. However, the chromosomal
DNA of the T. denticola CfpA-deficient cell was condensed in
distinct areas (Fig. 6E and F). Similar results were observed using
DAPI (data not shown).
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FIG. 6.
Chromosomal DNA visualization and localization with
Hoechst 33342 dye. (A) Dark-field microscopy of wild-type T. denticola and (B) the corresponding image by fluorescence. (C)
Group of wild-type T. denticola cells showing a similar
uniform DNA distribution. (D) Dark-field microscopy of T. denticola CfpA-deficient cells and (E) corresponding image
by fluorescence. Arrows indicate condensed DNA areas. (F)
T. denticola CfpA-deficient mutant cells, showing a typical
pattern of distribution. Arrows indicate condensed DNA areas. Bars, 10 µm.
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The location of the condensed chromosomal DNA in cells was
investigated. As shown in Fig.
5E and F, a small portion of the
cytoplasmic cylinder is occupied by the condensed chromosomal
DNA
labeled with the Hoescht 33342 dye. As mentioned above, under
the same
outer membrane there are multiple independent cytoplasmic
cylinders. In
a cell chain, each of the cytoplasmic cylinders
is delineated by the
pinch-like constrictions observed by dark-field
microscopy along the
cell (Fig.
6D). By comparing dark-field and
Hoeschst 33342 fluorescence
images, we were able to map the distribution
of the condensed
chromosomal DNA in the cytoplasmic cylinder of
single or chained cells
(Fig.
7). The cytoplasmic cylinder was
divided into three sections, independently of the length of the
cell.
The cytoplasmic cylinder extremities were designated E1
and E2, and the
center region was called C. Most of the cytoplasmic
cylinders contained
only one condensed DNA area (95%), with a
random distribution: 31%
found in the center and 64% found at
one end of the cytoplasmic
cylinder (Fig.
7A). When the distribution
of the condensed DNA area was
observed in two consecutive cytoplasmic
cylinders (Fig.
7B), there was
a preference for three patterns:
the central region and one of the
extremities in the other cytoplasmic
cylinder (C1-E3 [18%] and C1-E4
[18%]) and two facing extremities
(E2-E3 [25%]).
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FIG. 7.
Schematic representation of the distribution of
condensed chromosomal DNA in the T. denticola CfpA-minus
mutant. (A) Distribution in a single cytoplasmic cylinder (142 cytoplasmic cylinders). E1 and E2, extremities of the cytoplasmic
cylinder; C, center region. For example, in Fig. 5F, the upper right
corner cell has one cytoplasmic cylinder and bears the pattern E1-C-E2.
(B) Distribution in two adjacent cytoplasmic cylinders (55 cytoplasmic
cylinder pairs). The bar between the two schematic cytoplasmic
cylinders indicates that they are under the same outer membrane. E1 to
E4, extremities of the cytoplasmic cylinder; C1 and C2, center regions.
For example, in Fig. 5F, the lower left corner cell bears two patterns,
E4-C1 and C1-C2.
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When single cells with a single cytoplasmic cylinder, as defined above
by comparison of dark-field and fluorescence microscopy,
was observed,
a pattern distribution similar to that shown in
Fig.
6A was found (18 cells, E1 [58%], C [39%], and E1-C-E2 [5%]).
When single cells with two cytoplasmic cylinders, as described above,
were observed, only the E1-E3 pattern was not represented
(24 cells, E2-E3 [30%], C1-E3 [30%], C1-E4 [12%], C1-C2
[4%],
E1-E4 [8%], E1-E2-C2 [8%], E2-E3-C2 [4%], and
E1-E2-E4 [4%]).
At mid-log phase, the percentage of anucleated cytoplasmic cylinders
was 4.74% ± 0.74% for the cytoplasmic filament-less mutant,
versus
2.74% ± 0.47% for wild-type
T. denticola.
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DISCUSSION |
Discovered by electron microscopy, cytoplasmic filaments have been
observed in treponemes (16, 18) and certain other
spirochetes (3, 17). However, no function has been
associated with these distinctive structures. Their proposed
hypothetical functions were involvement in cell structure, cell
motility, and cell division (8). Other cytoplasmic
filament structures such as microtubules, tubules, fibers, fibrils, and
filaments have been described in prokaryotes, but their function is
unknown. The shape, length, striation, and number of these structures
vary (for a review, see reference 4). In T. denticola, the cytoplasmic filaments are permanent and are found
at all stages of cell division and growth; together with their
organization in a ribbon-like structure, their apparent lack of
involvement in cell shape differentiates them from the filament
structures observed in E. coli and Bacillus subtilis, such as the ones formed by FtsZ. The CfpA-deficient mutant phenotype includes the presence of chained cells, altered motility, and chromosome condensation. Thus, we hypothesize that the
cytoplasmic filaments are involved in cell division, chromosome segregation, or structure maintenance.
Due to chromosomal DNA condensation in the cytoplasmic
filament-deficient mutant, we were able to analyze the distribution of
the nucleoid in the cytoplasm of a population undergoing exponential growth. Chromosome segregation, arrangement, structure, and duplication are critical elements for the cell. For duplication, the two
replication forks initiate from oriC and meet at the
opposite side in the terminus region (12, 34). The
oriC and terminus region have a defined location in the cell
(36, 52), and between them, the chromosome regions are
laid out according to the order of replication (36, 46).
The factory model of replication proposed by Lemon and Grossman
(26) in B. subtilis implies that the replisome should be located at the cell center. Electron microscopy
autoradiography experiments lead to the same conclusion for E. coli (25). In Mycoplasma capricolum, the
nucleoid is centrally located (43). The presence of a
replisome cannot yet be generalized to all bacteria. However, if a
replisome does exist, it should migrate after cell septation from the
previous central region (designated C in Fig. 7A) that became two end
regions of the two newly formed cytoplasmic cylinders (E2 and E3 in
Fig. 7B), to the new central regions in each newly formed cytoplasmic
cylinders (C1 and C2 in Fig. 7B). In the cytoplasmic filament-less
mutant, the distribution of the condensed DNA in two consecutive
cytoplasmic cylinders follows the rules of this concept, as shown in
Fig. 7. We propose that the condensed chromosomal DNA progresses from
pattern C to pattern E2-E3 or C1-C2. However, not all the cells possess
a pattern directly described by the model. These can be explained as
follows. In a cell with multiple cytoplasmic cylinders, two adjacent
cytoplasmic cylinders at different stages of cell division would result
in a C1-E3 pattern. The patterns C1-E4 and E1-E4 would be the expected result of two adjacent cytoplasmic cylinders (with pattern E2-E3) which
have undergone a non-synchronized cell division process. The pattern
E1-E3 could be the result of two adjacent cytoplasmic cylinders (with
pattern E2-E3) in which only one has undergone the cell division
process. Other patterns could be the result of unsuccessful chromosome
transfer events resulting in cells without a nucleoid. In the absence
of cytoplasmic filaments, chromosomal DNA replication continues, and
the location of the condensed DNA after replication is in accordance
with the presence of a replisome in T. denticola.
Because of the unique structure of the cytoplasmic filaments, their
location, and their participation in the cell division process, it is
unclear how the filaments interact with the chromosome. Even if the
model of duplication and separation of oriC and
ter differs between E. coli and B. subtilis, the existence of an active chromosome segregation
mechanism seems unambiguous (10, 23, 36, 44, 51). Many
genes are involved in chromosomal DNA segregation. The mechanism that
spatially and temporally controls and directs the oriC
region is unknown; however, it seems likely that this mechanism
involves the action of a hypothetical spindle or mitotic-like apparatus
and "motor" proteins (44). The genetic analysis of
mutants shows a potential nucleoid segregation role for numerous genes.
Some of these genes are involved in DNA replication, cell division,
structural maintenance of chromosome, or SOS system, or they encode
histone-like proteins (1, 5, 6, 9, 11, 20, 22, 23, 54).
Others were associated with the formation of anucleate cells (13,
14) or polyploidy (48). There is no clear
understanding of how the genes interact, their degree of involvement,
and when they intervene. However, none of them are candidates to form a
filamenteous structure involved in a mitotic apparatus.
Filamentous structures that may be involved in nucleoid segregation are
CafA, CfpA, and some noncharacterized structures (4, 8, 38,
53). There is no phenotypic change in a cafA deletion mutant (49, 50). However, the cytoplasmic
filament-deficient mutant phenotype described in this report includes
chained cells and condensed DNA areas along the cytoplasmic cylinder,
indicating a cell division defect as well as a chromosome structure
alteration. The cytoplasmic filaments may be part of a mitosis-like
apparatus involved in chromosome segregation in T. denticola, allowing proper organization of the chromosomal DNA in
the cytoplasm. We found a nearly twofold increase in anucleated cells,
which could suggest a segregation defect. However, the observed
increase in the number of anucleated cells in the cytoplasmic
filament-less mutant compared to the wild type in log phase suggests
that the filaments do not have a critical role in the chromosome
segregation process.
The structure of the nucleoid is the result of DNA packaging, which is
the result of short- and long-range structure of the DNA and RNA,
macromolecular crowding and the effect of proteins that directly bind
to the DNA or actively modify chromosomal DNA topology
(39). We were not able to determine the number of
chromosomal DNA copies in the wild type compared to the cytoplasmic
filament-deficient mutant. However, it seems that in the CfpA-deficient
cells, the DNA is highly condensed. The cytoplasmic filament protein
consequently could be involved in "spreading" the DNA in the
cytoplasm. The structural consequences of this topological arrangement
would be a distribution of the chromosome subdomains on a greater
distance on the long axis of the cell than in E. coli or
B. subtilis.
The helical or flat wave-shaped treponemal cell, in conjunction with
the movement created by the periplasmic flagellar filaments, is
proposed to be the determinant of the unique ability of spirochetes to
penetrate dense media and cell layers (15, 47). In
Borrelia burgdorferi, a spirochete lacking cytoplasmic
filaments, a flagellar filament-deficient mutant has rod-shaped cells
(35, 42). In T. phagedenis and T. denticola, the absence of periplasmic flagellar filaments does not
significantly alter the cell shape other than the distal cell ends;
there is release of the stress applied to the outer membrane, and the
cell body maintains the waved or helical shape (7, 30,
41). One proposal (8) was that the cytoplasmic filaments were involved in maintaining the helical cell shape. The
results presented here show that the absence of cytoplasmic filaments
does not significantly alter T. denticola cell shape.
The cell motility generated by the rotation of periplasmic flagellar
filaments is unique to spirochetes (2, 28). Since the
absence of the periplasmic flagellar filaments eliminates motility in
dense media, the close apposition of the cytoplasmic filament to the
inner membrane beneath the periplasmic flagellar filaments (8,
18, 19) raised the question of a relationship between the two
structures during cell propulsion. The results presented here show that
under dark-field microscopy at 36°C at the single-cell level in
T. denticola, there is no obvious difference in motility
between the wild-type bacteria and the cytoplasmic filament-less mutant.
In summary, the evidence presented here suggests a role for the
cytoplasmic filaments in the cell division process or in chromosome structure or segregation. However, the precise role of the cytoplasmic filaments is not yet clearly understood. There is no similarity between
the cytoplasmic filament protein sequence and any other open reading
frame currently known. Evolution may have allowed different molecules
to maintain the same function or use different strategies. The study of
this persistent structure and its protein partners will bring new
critical data on cell division and chromosome structure maintenance and
an understanding of the mechanisms involved in transient or permanent
structures to be discovered in other bacterial genera.
| |
ACKNOWLEDGMENTS |
We thank Linda L. Slivienski and the Wadsworth Center Molecular
Genetics, Electron Microscopy, Molecular Immunology, and Photography core facilities.
This work was supported by Public Health Service grant AI34354 from the
National Institutes of Health.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Wadsworth
Center, David Axelrod Institute for Public Health, New York State
Department of Health, P.O. Box 22002, Albany, NY 12201-2002. Phone:
(518) 474-4177. Fax: (518) 486-7971. E-mail:
Jacques.Izard{at}wadsworth.org.
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Journal of Bacteriology, February 2001, p. 1078-1084, Vol. 183, No. 3
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.3.1078-1084.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
