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Journal of Bacteriology, October 2000, p. 5793-5798, Vol. 182, No. 20
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Myxococcus xanthus dif Genes Are
Required for Biogenesis of Cell Surface Fibrils Essential for Social
Gliding Motility
Zhaomin
Yang,1,
Xiaoyuan
Ma,1
Leming
Tong,1
Heidi B.
Kaplan,2
Lawrence J.
Shimkets,3 and
Wenyuan
Shi1,*
School of Dentistry, Molecular Biology
Institute and Dental Research Institute, University of California, Los
Angeles, California 90095-16681;
Department of Microbiology and Molecular Genetics, University
of Texas Medical School, Houston, Texas 770302;
and Department of Microbiology, University of Georgia, Athens,
Georgia 306023
Received 29 March 2000/Accepted 31 July 2000
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ABSTRACT |
Myxococcus xanthus social (S) gliding motility has been
previously reported by us to require the chemotaxis homologues encoded by the dif genes. In addition, two cell surface structures,
type IV pili and extracellular matrix fibrils, are also
critical to M. xanthus S motility. We have demonstrated
here that M. xanthus dif genes are required
for the biogenesis of fibrils but not for that of type IV pili.
Furthermore, the developmental defects of dif mutants
can be partially rescued by the addition of isolated fibril materials.
Along with the chemotaxis genes of various swarming bacteria and the pilGHIJ genes of the twitching bacterium
Pseudomonas aeruginosa, the M. xanthus dif genes belong to a unique class of
bacterial chemotaxis genes or homologues implicated in the biogenesis
of structures required for bacterial surface locomotion. Genetic
studies indicate that the dif genes are linked to the M. xanthus dsp region, a locus known to be crucial for
M. xanthus fibril biogenesis and S gliding.
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INTRODUCTION |
Myxococcus xanthus is a
gliding bacterium that exhibits complex multicellular development
(14). When deprived of nutrients on an appropriate surface,
M. xanthus cells use gliding motility to aggregate into
multicellular structures referred to as fruiting bodies. Although the
mechanism of M. xanthus gliding is not known, studies have
indicated that M. xanthus gliding motility is regulated by
two genetically separable systems, the A (adventurous) and S (social)
motility systems (18, 19). Mutations in either the A- or
S-motility genes inactivate the corresponding systems; however, the
cells are still motile by means of the remaining system. Whereas
A motility is described as motility of well-isolated cells or small
cell groups, S motility requires cell proximity or social
interaction to function (18, 19, 21, 32). S motility appears
more crucial for development than A motility because all of the known
M. xanthus S-motility mutants are defective to various
degrees in fruiting body development (19, 23).
Two M. xanthus cell surface appendages, pili and fibrils,
are required for S motility. M. xanthus pili belong to the
bacterial type IV pilus family (39). Numerous experiments
and reports have demonstrated the absolute requirement of the polar
type IV pili for M. xanthus S motility. The removal of pili
either by genetic mutations or by mechanical shearing leads to
S-motility defects (20, 27, 39). M. xanthus
fibrils are thought to be peritrichous, filamentous structures 10 to 30 nm in diameter and can be many times the length of the cells (13,
22). They have been observed to link neighboring cells or to link
cells to the substratum they glide over (2, 5, 26). The
fibril-defective dsp mutants are deficient in S motility
(2, 3, 29). Chemical disruption of M. xanthus
fibrils also results in S-motility defects (3). M. xanthus fibrils consist of approximately equal amounts of proteins
and carbohydrates (4). The presence of fibrils correlates
well with the specific carbohydrate content and phosphoenolpyruvate carboxykinase activity (22, 26). Recent observations with new techniques indicate that the presence of fibrils on M. xanthus is probably more extensive than previously thought
(22). Readily apparent on wild-type cells is a surface layer
of fibrillar materials that are evenly distributed over the cell
surface (22).
Our previous study showed that a new genetic locus, dif,
which encodes a new set of chemotaxis homologues, is required for S
motility (43). Here we report that the dif locus
is required for the biogenesis of extracellular matrix fibrils which
are crucial for S motility. Through various assays, we demonstrate that
dif mutants are defective in fibril biogenesis. The
developmental defects of the dif mutants can be partially
rescued by adding isolated fibril materials. Furthermore, the
dif genes were linked to the previously known dsp
mutations that result in similar defects in cellular cohesion, S
motility, and development (2, 3, 29, 30).
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MATERIALS AND METHODS |
Bacterial strains, growth conditions, and genetic
manipulation.
The M. xanthus strains used in this study
are listed in Table 1. For maintenance,
M. xanthus strains were grown at 32°C on CYE medium
(9) plates for 48 h and then stored at room temperature for up to 10 days. Liquid cultures were grown at 32°C in CYE medium on a rotary shaker at 250 rpm. Genetic crosses were conducted by
generalized transduction mediated by M. xanthus phage Mx4
(25).
Agglutination assays and rescue of cohesion and development.
The cohesion of M. xanthus cells was initially measured by
an agglutination assay developed by Shimkets (29) and later
modified by Wu et al. (41). Cells were grown and analyzed in
CYE medium. The optical density (OD) at 600 nm was measured with a
Shimadzu BioSpec-1601 spectrophotometer. The agglutination index was
expressed as relative absorbance equal to the OD reading at a given
time normalized against the initial OD (41).
Fibril materials were isolated from wild-type strain DK1622 and
quantitated as described previously (
6,
10). For analysis
of
the rescue of cohesion by isolated fibrils, the method of Chang
and
Dworkin (
10) was used with the following modification. One
milliliter of a cell suspension at 2.5 × 10
8 cells
per ml in cohesion buffer (10 mM morpholine propanesulfonic
acid
[MOPS; pH 6.8], 1 mM CaCl
2, 1 mM MgCl
2) with
isolated fibril
materials at carbohydrate concentrations of 30 to 80 µg/ml was
mixed and transferred to a semimicrocuvette. The cuvette
was sealed
with Parafilm, and the samples were incubated at room
temperature
in the dark. The OD at 600 nm was measured at different
time points.
To increase the sensitivity of this assay, the optical
surfaces
of the cuvette were covered with black paper so that the light
beam went through only the upper one-quarter of the
cuvette.
Developmental rescue of the
dif mutants was performed as
described previously (
10). Briefly, cells were harvested,
washed
once with 10 mM MOPS, and then resuspended in cohesion buffer
with fibril carbohydrates at 1.0 or 1.5 mg/ml. The final cell
density
in the mixture was adjusted to 2.5 × 10
9 cells per
ml. A 50-µl volume of the cell mixture was spotted
onto TPM agar (10 mM Tris-HCl [pH 7.6], 1 mM potassium phosphate
buffer, 8 mM
MgSO
4). After 48 h of incubation at 32°C,
development
of the
M. xanthus strains was observed and
documented. Cells were
scraped from the plates after photography and
treated with 1%
sodium dodecyl sulfate (SDS). The refractile and
SDS-resistant
spores were examined qualitatively under a phase-contrast
microscope.
Detection of pili and fibrils.
Samples containing M. xanthus cell surface pili were prepared by vortexing and
differential precipitation as described previously (36).
These samples were separated by SDS-polyacrylamide gel electrophoresis
(PAGE) and analyzed for the presence of pilin by immunoblotting with
polyclonal anti-PilA antibodies (40). Negative staining and
transmission electron microscopy (TEM) were used to examine the
presence of pili as described previously (39). For the
detection of fibril-specific proteins, whole-cell lysates were prepared
and analyzed by immunoblotting using MAb2105, a monoclonal antibody
against fibril-specific proteins (5, 6). For
fluorescence-activated cell sorter (FACS) analysis of fibril proteins
on cell surfaces, whole-cell immunofluorescent labeling was performed
according to Current Protocols in Molecular Biology (38). MAb2105 was used as the primary antibody, and a goat
anti-mouse immunoglobulin G (Fab-specific) fluorescein isothiocyanate
conjugate (Sigma, St. Louis, Mo.) was used as the secondary antibody.
FACS analysis was performed with a Coulter Epics Elite ESP
flow cytometer. The carbohydrate moiety of fibrils was examined by the
binding of calcofluor white as previously described (26).
Physical examination of fibrils was performed by scanning electron
microscopy (SEM) of M. xanthus cells deposited on glass
chips as previously described (5).
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RESULTS |
dif mutants are defective in cellular cohesion.
Cellular cohesion is closely correlated with M. xanthus S
motility. The cohesion of wild-type M. xanthus strains and
S-motility-defective dif mutants (43) was
examined using the agglutination assay (41). As shown in
Fig. 1, wild-type cells agglutinated as
expected. In contrast, the dif mutants (SW501, SW504, and
SW505) did not agglutinate over a 3-h period. Even after 24 h, the
mutants showed no obvious signs of agglutination. Because cell cohesion
measured by this assay depends on the presence of both pili and fibrils (41), the lack of cohesion exhibited by the dif
mutants could result from defects in the biosynthesis or assembly of
pili, fibrils, or both of these cell surface elements.
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FIG. 1.
Agglutination defects of dif mutants. Cells
were grown overnight in CYE medium, and the OD at 600 nm was adjusted
to about 0.5. The agglutination assay was then conducted as described
in Materials and Methods.
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Pili are present on the dif mutant cell surface.
The presence of pili on M. xanthus cells was first examined
by a procedure described previously (36). Samples containing cell surface pilin from various M. xanthus strains were
prepared and analyzed by immunoblotting with anti-PilA serum (Fig.
2A). A band of about 25 kDa was detected
in both wild-type strain DK1622 (lane 4) and dif mutant
strains SW501, SW504, and SW505 (lanes 1 to 3), indicating the presence
of pili on the cell surfaces (36, 40). Samples from DK1253,
an S-motility mutant known to be defective in piliation
(20), did not react to the antiserum as expected (lane 5).
The samples from the dif (Fig. 2) and dsp (data
not shown) mutants consistently reacted more strongly to the anti-PilA
serum, even though samples from equal amounts of cells were loaded onto
the gel. The reasons for such increases have not been fully
investigated. To confirm the piliation of these dif mutants,
they were further examined by negative staining and TEM. Figure
3A shows the piliation of
SW501, the difE mutant. Both difA mutants (SW504
and SW505) were piliated to an extent similar to that of the
difE mutant (data not shown). Therefore, the cohesion and
S-motility defects of these dif mutants are not due to the
lack of pili.
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FIG. 2.
Immunoblot analysis of pilus- and fibril-specific
proteins. All samples were separated by SDS-10% PAGE (28).
The presence of pilus- and fibril-specific proteins was analyzed using
anti-PilA serum (A) and monoclonal antibody MAb2105 (B) as primary
antibodies, respectively. In panel A, samples from 5 × 108 cells were loaded on each lane. Whole-cell lysate from
5 × 107 cells was loaded on each lane in panel B. Panel A lanes: 1, SW505; 2, SW501; 3, SW504; 4, DK1622; 5, DK1253.
Panel B lanes: 1, DK1622; 2, DK1253; 3, DK1300; 4, SW505; 5, SW501; 6, SW504; 7, DK3470.
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FIG. 3.
Examination of pili and fibrils by electron microscopy.
The presence of pili on SW501 cells was examined by negative staining
and TEM (A). SEM was used to examine the presence of fibrils on cells
of both wild-type (DK1622) and difE mutant (SW501) strains
(B). Bars, 2 µm.
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dif mutants are defective in the synthesis or assembly
of extracellular matrix fibrils.
The presence of fibrils on the
difE and difA mutant cell surface was first
examined by FACS analysis. Monoclonal antibody MAb2105, which
reacts with fibril-specific protein antigens (5, 6), was
used as the primary antibody for the immunolabeling. Figure
4 shows the results of such analyses, in
which difE mutant cells were compared with wild-type DK1622
cells. Whereas the majority of wild-type cells reacted with MAb2105,
very few of the difE mutant cells were labeled under the
same conditions. The difA mutant cells, similar to those of
the difE mutant, did not react to MAb2105 (data not shown).
Thus, the fibril-specific proteins recognized by MAb2105 are presumed
to be absent from the surface of dif mutant cells.
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FIG. 4.
FACS analysis with monoclonal antibody MAb2105.
Histograms from FACS analyses of DK1622 and SW501 cells are displayed.
Total numbers of cells analyzed: DK1622, 155,831; SW501, 122,003.
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The major nonprotein component of the
M. xanthus fibrils is
the carbohydrates or the extracellular polysaccharides which are
believed to form the backbone of fibrils (
4). The presence
of these polysaccharides on the
M. xanthus cell surface was
visually
examined by the binding of a fluorescent dye, calcofluor white
(Fig.
5). DK1622 cells bound calcofluor
white and showed fluorescence
under UV light as a result. The mutant
cells showed no detectable
binding of the dye by this assay. The lack
of calcofluor white
binding by the mutant cells indicates that the
dif mutants are
also defective in the biosynthesis or export
of exopolysaccharides.
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FIG. 5.
Calcofluor white (fluorescent dye) binding of M. xanthus. A 10-µl volume of a cell suspension (5 × 107 cells/ml) was spotted onto CYE medium plates containing
calcofluor white (50 µg/ml). After 7 days of incubation at 32°C,
dye binding was examined and documented using a handheld
long-wavelength UV light source and photography.
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SEM was used to examine the wild-type
M. xanthus strain and
the
dif mutants for the presence of
M. xanthus
fibrils. Figure
3B compares the SEM images of
difE mutant
SW501 and wild-type
DK1622. Fibrils are present on DK1622 cells and
absent from SW501
cells. Similarly, no extracellular fibrils were
detected on the
surfaces of
difA mutants SW504 and SW505.
These results demonstrate
that
dif mutations affect the
biosynthesis and/or assembly of
both the carbohydrate and protein
components of
M. xanthus fibrils.
The absence of the fibril-specific protein antigens from the cell
surface could result from defects in the export of proteins
containing these antigens to the cell surface. In this case, it
might be possible to detect the antigens within the cell. To
address
this possibility, whole-cell lysates were separated by SDS-PAGE
and analyzed by immunoblotting (Fig.
2B) using MAb2105 as the
primary
antibody. Multiple bands of the wild-type cell lysate
(lane 1) were
detected as previously described (
5). The cell
lysate of a
dsp mutant (DK3470) which is defective in fibril production
did not react to MAb2105 (lane 7). The reaction of cell lysates
of two
pilus-defecfive S-motility mutants, DK1253 and DK1300 (lanes
2 and 3)
(
20), was similar to that of the wild type. These data
indicate that defects in S motility and piliation per se do not
necessarily result in defects in the biosynthesis of fibril protein
antigens. In contrast, the
dif mutant cell lysates (lanes 4 to
6) did not react to MAb2105, indicating that there are no detectable
fibril-specific protein antigens associated with the mutant cells.
The
data may suggest that the
dif mutants are defective in the
biosynthesis of these fibril protein antigens or that there is
a
feedback inhibition preventing the accumulation of these proteins
inside cells. Another possibility is that the proteins are synthesized
and transported but not maintained on the cell surface. It is
also
possible that if these mutants are blocked in fibril protein
transport
or assembly, the proteins inside cells are not stable
enough to be
detected.
Isolated fibril materials can partially restore cohesion and
development to dif mutants.
We examined whether the
dif mutants could be rescued by the addition of isolated
fibrils. Different concentrations of isolated fibril materials were
added to mutant cell suspensions, and cohesion was measured by the
agglutination assay. The data in Fig. 6
show that cohesion, although delayed compared with that of wild-type cells, was restored to all of the dif mutants when fibrils
were added. At fibril carbohydrate concentrations of 40, 60, and 80 µg/ml, cohesion of the mutant cells occurred essentially at the same
rate. The rate of cohesion with fibrils at 30 µg/ml or below decreased in a dosage-dependent manner (data not shown). This observed
dosage-dependent response is consistent with previous reports
(10).
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FIG. 6.
Effects of isolated fibrils on cellular adhesion of
M. xanthus dif mutants. Cell suspensions (2.5 × 108 cells/ml) with or without fibrils
(carbohydrate-equivalent concentration, 40 µg/ml) were analyzed by
agglutination. Relative absorbance at 600 nm was used as the cohesion
index.
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To determine if the addition of fibrils could rescue the ability of the
dif mutants to form fruiting bodies, fibrils were
added to
dif mutants at fibril carbohydrate concentrations of
1.0 and
1.5 mg/ml and the cells were subjected to development-inducing
conditions. The results for SW501 and SW505 are shown in Fig.
7. At 1.5 mg/ml, all three
dif
mutants (SW501, SW504, and SW505)
formed fruiting bodies. However, the
rescue at 1.0 mg/ml was less
complete; loose and irregular fruiting
bodies or aggregates were
observed. Nevertheless, at both
concentrations, the fruiting bodies
and the aggregates darkened after
48 h and contained spherical,
refractile, SDS-resistant
myxospores, as indicated by examination
of an SDS-treated sample
by phase-contrast microscopy. DK3470,
the
dsp mutant, could
also be rescued in a similar fashion, as
expected (data not
shown).
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FIG. 7.
Developmental rescue of dif mutants by
isolated fibrils. The final fibril concentration in cell suspension
(2.5 × 109 cells/ml) is indicated at the top as the
equivalent of fibril carbohydrates. The experiments were conducted
under development-inducing condition as described in Materials and
Methods. Shown are the rescues of SW501 (A) and SW505 (B).
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dif genes are linked to the dsp
region.
Our characterization of the dif mutant
phenotypes indicates that they are identical or similar to the
previously isolated dsp mutants. This has driven us
to examine if dif mutations are linked to the dsp
region. dsp mutations are linked to the Tn5 insertion 
DK1407 (30). To examine the possible linkage
between dif genes and the dsp region, SW501
(containing difE::Kanr) was used as the donor
and LS300 (containing DK1407 Tn5-132) was used as the
recipient in an Mx4-mediated transduction. Of the 249 kanamycin-resistant transductants obtained, 160 had lost the
tetracycline resistance marker (Tn5-132), indicating 64%
cotransduction of the wild-type locus of the DK1407 insertion and
the difE insertion mutation. According to the Wu equation
(31, 42), this cotransduction frequency represents a
physical distance of about 7.7 kb between difE and
DK1407, indicating that the dif genes are at or near the
dsp region (30).
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DISCUSSION |
There are three major mechanisms of active bacterial surface
translocation: gliding, twitching, and swarming (17). As
described in the introduction to this report, M. xanthus is
one of the best-studied gliding bacteria. Swarming motility is
widespread among eubacteria (16, 17) and has been
extensively studied in Vibrio parahaemolyticus, Proteus mirabilis (1, 7, 24), and recently in
Serratia liquefaciens, Escherichia coli, and
Salmonella typhimurium (8, 15, 16). On
appropriate surfaces, these bacteria undergo a series of changes and
transform from "swimmer" cells to differentiated "swarmer"
cells. During this differentiation, cell septation ceases and the cell
body elongates. Generally, swarmer cells are more flagellated than
liquid-grown swimmer cells. In addition, extracellular polysaccharides or slimes often encapsulate swarmer cells.
Twitching motility has been best studied in the opportunistic
pathogen Pseudomonas aeruginosa (12). Although
the mechanism of twitching motility is not yet understood,
experimental evidence clearly indicates that type IV pili are
indispensable. All of the P. aeruginosa pil mutants
defective in type IV pilus biogenesis are unable to display twitching
motility (12). Suggestions have been made that the bacterial
type IV pilus is a novel type of motor for surface translocation
(32, 35).
M. xanthus S motility shares similarities with both
twitching and swarming. Type IV pili are required for both M. xanthus S motility (20, 39) and P. aeruginosa twitching motility (12). Swarming
motility is strictly a multicellular phenomenon, as single cells
emerging from the moving mass are stranded and cease to move
(34). Likewise, S motility is a multicellular behavior requiring cell proximity. Consequently, S-motility flares and advancing
rafts of swarming bacteria appear strikingly similar to each other
(16, 29). In addition, chemotaxis genes or homologues are
required for swarming, twitching, and M. xanthus S motility. Studies on a few swarming bacteria have demonstrated that chemotaxis systems play critical roles in swarming motility (16). The
P. aeruginosa pilGHIJ cluster encodes a set of chemotaxis
homologues required for twitching motility (11). In both
twitching and swarming, these chemotaxis genes or homologues appear to
be essential for the biogenesis of cell surface structures instead of
directed cell movements. For example, the chemotaxis genes in E. coli are required for the differentiation and hyperflagellation of
swarmer cells (8) and the P. aeruginosa pilGHIJ
genes are essential for the biogenesis of type IV pili (11).
The M. xanthus frz genes (37), encoding
chemotaxis homologues (43), are required for directed cell
movement but not for S motility (37). Prior to this report,
there has been no evidence indicating the involvement of chemotaxis
genes or homologues in the biogenesis of cell surface structures
required for M. xanthus gliding motility. In this study, we
have determined that dif genes are required for the
biogenesis of fibrils in M. xanthus. Thus, the
dif genes are members of a small group of chemotaxis genes
or homologues essential for the biogenesis of structures required for
bacterial surface translocation. These findings appear to suggest a
common theme among twitching, swarming, and M. xanthus S motility; that is, certain chemotaxis genes or
homologues have essential functions in all three forms of bacterial
surface translocation by regulating the biogenesis of surface structures.
How these chemotaxis genes or homologues regulate a biogenesis process
is not clear. The regulation of the biogenesis of these various surface
structures could be distinct for each motility system. The regulation
of M. xanthus fibril biogenesis by dif genes may
occur by two alternate mechanisms which are not mutually exclusive. The
dif genes may regulate the biosynthesis of fibrils, or they
may regulate their assembly. We do not have evidence to support either
mechanism. The chemical composition of M. xanthus fibrils
makes distinguishing between these two mechanisms complicated. M. xanthus fibrils contain about equal amounts of protein and carbohydrate, which together account for approximately 85% of the dry
weight of fibrils (4). The whole-cell lysates from mutant
cells contained no protein antigens reactive with MAb2105 (Fig. 2),
which may suggest that such protein antigens are not synthesized in
dif mutants. However, the association between fibril proteins and carbohydrates is not yet understood. Since the
carbohydrates appear to form the backbone of M. xanthus
fibrils (4), the protein materials could be anchored to cell
surfaces by the fibril carbohydrates. Defects in the transport or
assembly of the carbohydrate backbone may lead to the loss of such
proteins at cell surfaces even if they are produced. Alternatively, if
the proteins cannot be transported correctly, they may be degraded
within the cells or their synthesis may be inhibited. The development
of new assays and further biochemical characterization of the fibrils
should facilitate the understanding of the associations and
interactions between the carbohydrate and protein components of fibrils
and help to elucidate the mechanism by which dif genes
regulate fibril biogenesis.
What roles do the fibrils play in M. xanthus social
motility? It has been suggested that M. xanthus fibrils
provide the major force for cell cohesion and, as a result, maintain
the integrity of M. xanthus multicellular or S swarms
(2). The roles of fibrils in S motility probably go beyond
simple physical cohesion required for S motility. Genetic studies
(18, 19) clearly indicated that S motility is not a
collective movement of cell with A motility by physical attachment
because A-motility-defective mutants retain their S motility. Although
there have been suggestions that M. xanthus type IV pili are
the motor or part of a motor specific for S motility (39,
41), it is not clear how and by what structure the
mechanical force is generated for S gliding. It is clear, however, that
the S-gliding mechanism needs activation via cell proximity-related
signals (18, 19, 32). When cells with S motility
(A
S+) are isolated from one another, they
show no net translocation. However, when they are in proximity to one
another, motility is apparent (33). The S-motility defects
of dif mutants are distinct from those of pil
mutants. Similar to A dsp double mutants
(41), A dif double mutants show a
fringe around their colonies after prolonged incubation (data not
shown), indicating that the dif mutants retain some residual
S motility. The residual S motility of dif and
dsp mutants suggests that the components of the
S-gliding-specific motor have not been entirely eliminated in
these mutants. It is possible, instead, that it is the activation of
the S-gliding mechanism that is impaired in dif and
dsp mutants. Interestingly, cell proximity is also
required for bacterial swarming motility (16, 17).
Perhaps, the requirement for cell proximity reflects a common
activation mechanism in M. xanthus S motility and the swarming motility of other bacteria.
If we consider the possibility of an activation defect in
dif and dsp mutants, these genes may affect such
an activation process in two different ways. First, the effects of
dif and dsp genes on activation could be
indirect. Since both dif and dsp mutants lack
fibrils, it may be the lack of fibrils, rather than the lack of
dif and dsp gene products themselves, that
results in the motility defects. Fibrils can either be the activation
signal or facilitate the transmission of such a signal. It is
conceivable that fibril materials, which encircle and link M. xanthus cells, provide a suitable and managed microenvironment for
the transmission of signals of cell proximity. Interestingly,
differentiated swarmer cells also produce extracellular slimes composed
of polysaccharides. Second, dif and dsp genes may
play a more direct role in the activation process. The dif
gene products are expected to form a chemotaxis-like signal
transduction pathway that may potentially interact with the
S-gliding-specific motor, analogous to the way enteric bacterial chemotaxis genes interact with components of the bacterial
flagella. Further studies are necessary to determine how
dif and dsp regulate S motility.
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ACKNOWLEDGMENTS |
We are grateful to Martin Dworkin and Dale Kaiser for providing
antibodies and strains. We thank David Zusman and Martin Dworkin for
their enthusiasm and for very helpful discussions. We owe debts of
thanks to Alice Thompson and Birgitta Sjostrand for expert help with
electron microscopy, to Anahid Jewett for help with the flow cytometer,
and to Sharon Hunt Gerardo for critical reading and careful editing of
the manuscript.
This work was supported by NIH grants GM54666 to W. Shi and GM47444 to
H. Kaplan, NSF grant MCB9601077 to L. Shimkets, and NIH training grants
5-T32-AI-07323 and 5-T32-DE-07296 to Z. Yang.
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FOOTNOTES |
*
Corresponding author. Mailing address: School of
Dentistry, Molecular Biology Institute and Dental Research Institute,
University of California, Los Angeles, CA 90095-1668. Phone: (310)
825-8356. Fax: (310) 794-7109. E-mail: wenyuan{at}ucla.edu.
Present address: Department of Biological Sciences, Auburn
University, Auburn, AL 36849.
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Journal of Bacteriology, October 2000, p. 5793-5798, Vol. 182, No. 20
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Abstract
Introduction
