* Division of Infectious Diseases, Department of Medicine, Vanderbilt University School of Medicine, and the Department of
Veterans Affairs Medical Center, Nashville, Tennessee 37232-2605; Department of Pharmacology, Yale University, New
Haven, Connecticut 06510; and § Department of Cell Biology, Washington University School of Medicine, St. Louis, Missouri
63110
In this study, we describe the ultrastructural changes associated with acid activation of Helicobacter pylori vacuolating cytotoxin (VacA). Purified VacA molecules imaged by deep-etch electron microscopy form ~30-nm hexagonal "flowers," each composed of an ~15-nm central ring surrounded by six ~6-nm globular "petals." Upon exposure to acidic pH, these oligomeric flowers dissociate into collections of up to 12 teardrop-shaped subunits, each measuring ~6 × 14 nm. Correspondingly, glycerol density gradient centrifugation shows that at neutral pH VacA sediments at ~22 S, whereas at acidic pH it dissociates and sediments at ~5 S. Immunoblot and EM analysis of the 5-S material demonstrates that it represents ~90-kD monomers with 6 × 14-nm "teardrop" morphology. These data indicate that the intact VacA oligomer consists of 12 ~90-kD subunits assembled into two interlocked six-membered arrays, overlap of which gives rise to the flower-like appearance. Support for this interpretation comes from EM identification of small numbers of relatively "flat" oligomers composed of six teardrop-shaped subunits, interpreted to be halves of the complete flower. These flat forms adsorb to mica in two different orientations, corresponding to hexameric surfaces that are either exposed or sandwiched inside the dodecamer, respectively. This view of VacA structure differs from a previous model in which the flowers were interpreted to be single layers of six monomers and the flat forms were thought to be proteolysed flowers. Since acidification has been shown to potentiate the cytotoxic effects of VacA, the present results suggest that physical disassembly of the VacA oligomer is an important feature of its activation.
HELICOBACTER pylori is the cause of chronic superficial gastritis in humans, and infection with this organism predisposes the host to the development
of peptic ulcer disease and gastric adenocarcinoma (Telford et al., 1994b Purified H. pylori VacA migrates as an ~90-kD protein
under denaturing conditions but as an ~1,000-kD complex
under nondenaturing conditions (Cover and Blaser, 1992 Preparation of H. pylori VacA
H. pylori strain 60190 (American Type Culture Collection 49503; Rockville, MD), a well-characterized cytotoxin-producing strain with a type
s1a/m1 vacA genotype (Cover and Blaser, 1992 Isolation and Characterization of VacA by Glycerol
Density Gradient Centrifugation
As an alternate approach for purifying VacA, ammonium sulfate-precipitated supernatant proteins were fractionated by centrifugation through
glycerol density gradients. 1-ml aliquots of dialyzed samples (containing
about 10 mg total protein) were layered on 37-ml 10-35% glycerol gradients
in 60 mM Tris, pH 7.5, containing 100 mM NaCl and centrifuged at 28,000 rpm in an SW28 rotor (Beckman Instruments, Palo Alto, CA) for 20 h at
4°C (Martin and Ames, 1961 For analytical purposes, 5-ml 10-35% glycerol gradients were prepared
in either 60 mM Tris, pH 7.5, containing 100 mM NaCl, or 100 mM glycine, pH 3.0, containing 100 mM NaCl. 100-µl aliquots of samples (either
dialyzed ammonium sulfate-precipitated proteins from broth culture supernatant or VacA that had been partially purified by gel filtration chromatography as described above) were layered on the gradients and centrifuged for 7.5 h at 40,000 rpm in an SW50.1 rotor (Beckman Instruments).
For acidification, samples were typically brought to pH 3 by drop-wise addition of 0.1 N HCl while stirring and then incubated at 30°C for 10 min. Subsequent reneutralization was accomplished by drop-wise addition of
Tris base until the sample was brought back to pH 7.5. VacA oligomers also
dissociated when layered directly on a pH 3 glycerol gradient (i.e. without
prior acidification).
Electron Microscopic Imaging of VacA
In preparation for EM, VacA samples were adsorbed to a suspension of
finely ground mica flakes, followed by freeze-drying and platinum replication according to established procedures (Heuser, 1983 Quick-frozen mica flakes were then freeze-fractured in a Balzer's
freeze etch machine and "deep-etched" for 4 min at Replicas were viewed in a transmission electron microscope (JEOL
U.S.A., Inc., Peabody, MA) operated at 100 kV and were photographed in stereo using +10° of tilt with a eucentric side-entry goniometer stage.
Finally, representative molecules were chosen by 4× video imaging of micrographs initially taken at 68,000×, and their video images were transferred to a computer. Using Adobe Photoshop, they were enlarged to
300,000× for production of the photomontages shown here.
Cell Culture Methodology
Vacuolating cytotoxin activity was assessed by incubating HeLa cells for
24 h with serial dilutions of samples in a microtiter assay, as described previously (Cover et al., 1991 Deep-etch Imaging of the Vacuolating Cytotoxin
In initial experiments, we extracted high-molecular weight
proteins produced by H. pylori strain 60190 by ammonium
sulfate precipitation of broth culture supernatants and isolated the largest molecules by gel filtration chromatography on a Superose 12 HR 16/50 column. More than 90% of
the vacuolating activity of the culture supernatant eluted
in the void volume of such columns (Cover and Blaser,
1992
Closer examination of the flower shapes in such preparations (10 examples of which are presented in the top two
rows of Fig. 2) demonstrated that they are composed of
prominent central rings ~15 nm in diameter, surrounded
generally by six globular petals measuring 5-6 nm in diameter, yielding an overall diameter of ~30 nm for the entire
flower. VacA preparations purified further by glycerol density gradient centrifugation yielded identical images of six-sided flowers (not shown). As a control, we examined the
high-molecular weight components of culture supernatant
from an isogenic mutant strain of H. pylori (60190-v1) that
fails to produce VacA (Cover et al., 1994
By displaying predominantly six-sided flowers, the
VacA preparations generated in this study differed from
those generated in the previous deep-etch study of VacA,
in which approximately half of the flower-shaped complexes appeared to be seven sided (Lupetti et al., 1996
Although essentially all clinical isolates of H. pylori contain a vacA homologue, individual isolates differ markedly
in the quantity and activity of VacA produced, and several
different families of vacA alleles have been described
(Atherton et al., 1995 Two additional macromolecules produced by H. pylori
are HspB (a GroEL heat shock protein homologue) and
urease. These have estimated molecular masses of 750 and
550-650 kD, respectively (Hu and Mobley, 1990 Unidirectional Shadow-Castings of
H. pylori Macromolecules
To further analyze the three-dimensional structure of the
various forms of VacA, urease, and HspB, high-molecular
mass proteins were isolated from broth culture supernatant and imaged by "shadow-casting" according to classical techniques (Williams and Wyckoff, 1946
Shadow-castings highlighted important differences between the two different forms of VacA oligomers described above. The petals of the more typical VacA flowers
cast ~23-nm shadows, and their central rings cast ~40-nm
shadows, indicating that these domains were raised ~7
and ~12 nm above the mica, respectively (Fig. 4, first and
second rows). In contrast, the flat forms of VacA cast shadows that were never greater than 13 nm in length (Fig.
4, third row), indicating that no part of these structures
was raised above the mica by more than 3.5 nm. Thus, the
latter form was indeed much flatter than the flower form.
The implications of this roughly twofold difference in molecular thickness will figure centrally in the interpretation
of VacA structure presented below.
Relationship between the Structure of VacA and Its
State of Proteolysis
VacA secreted by H. pylori 60190 migrates under denaturing conditions as an ~90-kD band (Cover and Blaser,
1992 Effect of Acidification on VacA Structure
The vacuolating activity of VacA has been shown to increase substantially after exposure of the toxin to acidic
pH (de Bernard et al., 1995
A second approach by which we observed acid-induced
dissociation of VacA was to bring a solution of VacA oligomers to pH 3 by the slow addition of HCl, incubate it at
30°C for 10 min, and finally adsorb the products of this reaction to mica at pH 3 before EM imaging. This yielded
very few remnants of intact VacA oligomers, i.e., there
were only rare examples of groups of 6 × 14-nm petals clinging together with any sense of organization (Fig. 6,
fourth row). More frequently observed were free 6 × 14-
nm petals lying helter-skelter on the mica surface in no apparent relation to each other (Fig. 6, fifth row), or with
only an occasional tendency to dimerize (Fig. 6, lower right
panel).
Velocity sedimentation on glycerol density gradients
also indicated that acidification of VacA induced dissociation of the oligomeric form. Thus, when VacA was sedimented on a glycerol gradient at pH 7.5, a ~22-S peak was
obtained, whereas when VacA was acidified to pH 3 for 10 min at 30°C and applied to a pH 3.0 gradient, nearly 100%
of it sedimented in fractions corresponding to ~5 S (Fig. 7).
Immunoblotting the ~5-S fractions recovered from such
pH 3.0 gradients indicated that VacA was still in its intact
~90-kD form. Hence, VacA dissociation did not seem to
be dependent upon nor in any way associated with VacA
proteolysis. Deep-etch EM of the purified ~5-S fractions
yielded images of fully dissociated 6 × 14-nm petals identical to those shown in Fig. 6 (not shown). These 5-S fractions induced prominent cell vacuolation when added to
tissue culture medium overlying cultured HeLa cells (not
shown). Thus, dissociated VacA subunits were clearly not
denatured by prolonged exposure to pH 3. However,
whether the 5-S VacA monomer is the active vacuolating
species or whether it must repolymerize into an oligomeric
form when added to tissue culture media (at neutral pH)
remains to be determined.
Reassembly of the VacA Oligomer
To discriminate between these two possibilities, we next
sought to determine whether VacA monomers produced
by acidification could reassemble into oligomers upon reneutralization to pH 7. A VacA-containing preparation was
acidified to pH 3 by the addition of dilute HCl in the presence of constant stirring and incubated at 30°C for 10 min,
and then aliquots were either maintained at pH 3 or neutralized by the addition of Tris base. On glycerol gradients
at pH 3, the continuously acidified VacA aliquot yielded a
~5-S monomeric peak, as seen above. In contrast, when
sedimented through a pH 7.5 gradient, the acidified and
reneutralized aliquot again yielded a ~22-S peak, indicating that the VacA monomers had reannealed (Fig. 7). This
experiment was repeated after a preparation of VacA had
remained at pH 3 for 7.5 h, with identical results (not shown).
Deep-etch EM imaging of the reannealed ~22-S species
revealed that they were slightly less orderly in construction than the starting material but had in large part reacquired a flower-like appearance with prominent central
rings surrounded by relatively globular petals (Fig. 8). Residual disorder was manifest by an increased frequency of
bifurcated or "ectopic" petals (Fig. 8, arrowheads). This
gave the immediate visual impression of a much greater
than normal frequency of seven-sided flowers, approaching that seen in the earlier deep-etch study (cf. Fig. 3).
However, after all of the examples of petal "mismatch"
were discounted, the actual increase in the proportion of
oligomers with seven petals rather than six (Fig. 8) was
more modest (~10-30% increase).
Three-dimensional Analysis Reveals a Second Type of
Flat VacA Oligomer
Careful inspection of many replicas revealed that although
>95% of flat forms displayed a clockwise chirality (as
shown in Fig. 2), occasional flat forms could be found that
exhibited the opposite (counterclockwise) chirality (Fig. 9).
Importantly, central rings like those found in the typical
VacA flowers were clearly visible in these counterclockwise forms (Fig. 9), whereas central rings were absent
from the more common clockwise forms (Fig. 2). Indeed,
counterclockwise forms looked so much like the usual
flowers that they were not initially recognized as being
flatter until the replicas were examined carefully in three
dimensions. After presenting our model for VacA structure in the Discussion, we will explain why we interpret
these two different types of flat forms as being views of the
top and bottom faces of VacA hexamers. The presence of
a visible ring in only one of the two views is an indication
that the top and bottom surfaces of VacA hexamers are
not identical.
Based on the ultrastructural changes in VacA that are provoked by acidification, we propose a model in which the
intact VacA flower is composed of 12 ~90-kD subunits arranged as a symmetrical pair of six-membered arrays (Fig.
10). In this model, the flat VacA forms are thought to represent the individual six-membered arrays or halves of the
complete VacA dodecamer. One critical feature of the
model presented in Fig. 10 is that the six-membered flat
arrays are predicted to have two distinguishable faces, one relatively featureless and the other displaying a reduced
version of the central ring seen in the complete VacA
flower. These two views were distinguishable in three-
dimensional views such as in Fig. 9. A second feature of
the model is that the dodecamer is predicted to be formed
with "P2" symmetry, i.e., with its two component hexamers
oriented face-to-face. This conclusion was reached because
all VacA flowers looked the same in deep-etch replicas,
regardless of their orientation on the mica. An important consequence of this P2 symmetry, when combined with
the cant of individual VacA petals, is that the opposed
hexamers would lock together to form the particularly
close-knit complex shown (Fig. 10, right panel). Finally, a
third prediction of the model proposed here is that the
prominent central ring of the VacA flower would result
from two factors: (a) from overlap of central parts of the
petals in its two apposed hexamers, and (b) from outward
orientation of central rings in each hexamer, as is seen in
the rare counterclockwise flat forms shown in Fig. 9. It is
important to note, however, that if factor b were true, it
would raise the question of why intact VacA flowers do
not display the counterclockwise chirality seen in this sort
of flat form. We believe that this is most likely due to the
vagaries of platinum replication. The intact flowers stand
nearly twice as tall above the mica as the flat forms (Fig. 4)
and thus receive commensurately heavier coats of platinum. Fig. 11 illustrates how a heavier deposition of platinum could obscure the chirality of the upper hexamer.
The model of VacA proposed in Fig. 10 differs significantly from that proposed in a previous deep-etch EM
study (Lupetti et al., 1996 We were unable to separate flat forms from intact flowers, either by gel filtration chromatography or by density
gradient centrifugation. Coupled with our finding that
most flat forms occurred in clusters near the freeze-fractured surface of our replicas (see also Fig. 1 in Lupetti et al.,
1996 The fact that all of the petals in acid-dissociated 12-mers
display the clockwise chirality seen in most flat forms (Fig. 6), despite Fig. 10's prediction that VacA is assembled
with P2 symmetry (i.e., with the upper hexamer oriented
opposite from the lower), suggests that as the oligomers
fall apart in acid, the petals of the upper hexamer fall
down between the petals of the lower hexamer and rotate
to adopt the orientation of the lower ones. An alternate
explanation, which we believe is less likely, is that individual VacA monomers or petals actually have an intrinsic polarity that always makes them tend to adsorb to mica
with the clockwise orientation that is seen in most flat
forms. If this were true, it would suggest that VacA typically became "warped" during adsorption to mica and hence,
its observed chirality might be an artifact. However, the
identification of clear-cut examples of counterclockwise
flat forms (Fig. 9), which are most easily interpreted as
views of the opposite sides of the component hexamers, provides strong evidence that the VacA complex does indeed possess the intrinsic chirality shown in Fig. 10.
An additional finding in the present study was that the
dissociated ~90-kD VacA monomers generated by acidification were capable of reannealing into flower-like structures upon return to neutral pH. (This, of course, demonstrated that they were not completely denatured by the
exposure to acidic pH.) However, the reannealed VacA
oligomers appeared to display an increased proportion of seven-sided forms. Some of these obviously resulted from
a mismatch of petals between the two reannealing hexamers, as shown by the arrowheads in Fig. 8; but many were
as perfectly assembled as the seven-sided complexes shown
in Fig. 3. These demonstrated that VacA has a clear tendency to oligomerize into 14-mers as well as 12-mers under
reneutralizing conditions. As such, this raises the possibility that the preponderance of seven-sided VacA molecules
observed in the earlier deep-etch study of Lupetti et al.
(1996) The present results demonstrate that VacA behaves
somewhat like the cyclic pentameric complexes of cholera
toxin and Escherichia coli heat-labile enterotoxin B-rings
(CtxB and EtxB), which also disassemble when exposed to
acid pH (Ruddock et al., 1995 The original description of VacA activation by acidification reported that changes occurred in its circular dichroism and fluorescence spectra as well as in its proteolytic
fragmentation pattern but reported that no change occurred in its EM structure (de Bernard et al., 1995 Current evidence suggests that within acidic intracellular compartments, the B (binding) subunits of A-B type
toxins insert into membranes, which facilitates entry of enzymatically active A subunits into the cytosol (Montecucco et al., 1994; Blaser, 1996
; Cover and Blaser, 1996
).
Many H. pylori strains secrete a cytotoxin (VacA) that induces prominent vacuolation and degeneration of cultured eukaryotic cells (Papini et al., 1994
; Cover, 1996
). Direct
introduction of VacA into the stomachs of mice causes epithelial injury (Telford et al., 1994a
), and VacA activity is
thought to be important in the pathogenesis of peptic ulcer
disease in humans (Figura et al., 1989
; Atherton et al.,
1995
; Marchetti et al., 1995
).
;
Manetti et al., 1995
). Previous deep-etch electron microscopic work demonstrated that the VacA complex is a
"flower"-like oligomeric structure with six or seven visible
"petals," suggesting that it may be constructed similarly to A-B type bacterial toxins (Lupetti et al., 1996
). Additionally, previous tissue culture studies demonstrated that
the specific activity of VacA increases by more than an
order of magnitude after exposure to acidic pH (de Bernard
et al., 1995
). To analyze further the oligomeric structure of
VacA and to determine what happens to its EM structure
when activated by low pH, the present study was undertaken.
Materials and Methods
; Cover et al., 1994
; Atherton et al., 1995
), was cultured in ambient air containing 6% CO2 for 48 h at
37°C in sulfite-free Brucella broth (Hawrylik et al., 1994
) containing 0.5%
charcoal. After centrifugation of the culture at 10,000 g for 15 min, supernatant proteins were precipitated with a 50% saturated solution of ammonium sulfate and resuspended in 60 mM Tris, pH 7.5, containing 100 mM
NaCl. After passage through a 0.2-µm filter, supernatant proteins were
fractionated by gel filtration chromatography in 60 mM Tris, pH 7.5, containing 100 mM NaCl, using either a Superose 12 HR 16/50 or a Superose
6 HR 16/50 column (Pharmacia Biotech, Piscataway, NJ) (Cover and Blaser, 1992
). The presence of VacA in samples was detected by Western
blotting with rabbit anti-VacA serum, as described previously (Cover and
Blaser, 1992
). In addition to purifying VacA from H. pylori 60190, VacA
proteins also were purified from H. pylori strains with type s2/m2 and s1a/m2
vacA genotypes (86-338 and 95-54, respectively) (Atherton et al., 1995
).
). Gradients were fractionated from the top
using an Auto Densi-Flow IIC apparatus (Labconco Corp., Kansas City,
MO) and analyzed for VacA content by immunoblotting, as above. Standards were fractionated in parallel gradients and included BSA (4.6 S),
catalase (11.2 S), and thyroglobulin (19 S).
, 1989
). Briefly,
this involved adding two drops of a suspension of finely ground mica to 0.5 ml of a solution containing 10-30 µg purified VacA and allowing the toxin
to adsorb to the mica for 30 s. The mica flakes were then pelleted by gentle centrifugation, washed twice with a solution of 30 mM Hepes, pH 7.2, containing 70 mM KCl and 5 mM MgCl2, and layered onto a thin slice of
aldehyde-fixed lung for support during freezing. This was accomplished
by dropping the samples onto a liquid helium-cooled copper block in a
homemade "quick-freeze" device.
100°C, thereby exposing molecules adsorbed to the surfaces of the mica flakes. These were
then rotary-replicated with ~2 nm of platinum evaporated from an angle
of 11° above the horizontal, and finally "backed" or supported with a ~10-nm film of pure carbon. The replicas were cleaned of mica by floating
them overnight in concentrated hydrofluoric acid. The replicas were then
washed in water and finally picked up on 75-mesh formvar-coated microscope grids.
). In each experiment, Eagle's modified minimal
essential medium containing 10% FBS was supplemented with 5 mM ammonium chloride at the time of cytotoxin addition. Vacuolation was quantified by a neutral red uptake assay (Cover et al., 1991
) or directly visualized in living cells with video-enhanced time-lapse light microscopy
(Heuser et al., 1993
).
Results
). When this material was adsorbed to mica flakes and
examined by deep-etch EM (Fig. 1), it was found to contain a mixture of three molecular forms, including spheres, barrel shapes, and the striking flower shapes identified as
VacA in a previous deep-etch EM study (Lupetti et al.,
1996
).
Fig. 1.
Deep-etch survey view of the high-molecular mass proteins present in broth culture supernatant from H. pylori 60190 as
they appear after adsorption to mica and freeze-drying. Three
different types of macromolecules are visible, corresponding to
urease (spheres), HspB (barrels), and VacA (flowers). The panel
represents a field 0.7 µm in width.
[View Larger Version of this Image (175K GIF file)]
). Flower-shaped
complexes were not found in this preparation, which confirmed that the flowers represented oligomeric VacA.
Fig. 2.
Rotary replicas of
purified and freeze-dried H. pylori macromolecules. First
and second rows: Typical
VacA flowers purified from
broth culture supernatants of
tox+ H. pylori strain 60190 (type s1a/m1 vacA genotype).
Third row: VacA flowers purified from strain 60190 and
digested with trypsin for 5 h
before adsorption to mica.
(See Fig. 5 c for immunoblot analysis of the proteolytic
breakdown pattern of this
particular preparation.) Fourth
row: VacA flowers purified
from H. pylori strains 95-54 and 86-338 (type s1a/m2 and
s2/m2 vacA genotypes, respectively). Fifth row: Flat
forms of VacA found in low
abundance among the more
typical flowers shown in first
through third rows. Sixth
row: HspB molecules from
culture supernatant of H. pylori 60190-v1 (an isogenic
tox [] strain). Seventh row:
Urease molecules from culture supernatant of H. pylori 60190-v1. Magnification 300,00×. In this and all subsequent EM figures, each
panel represents a field 75 × 75 nm.
[View Larger Version of this Image (145K GIF file)]
Fig. 5.
Immunoblot analysis of intact and proteolysed
VacA preparations electrophoresed on a 10% acrylamide gel, transferred to nitrocellulose, and reacted with
a 1:10,000 dilution of rabbit
anti-VacA serum; the antigens were resolved as described previously (Cover
and Blaser, 1992). Lane a, intact ~90-kD VacA from H. pylori 60190; lane b, VacA
proteolytic fragments (34 and 58 kD) arising after prolonged storage of purified
VacA; lane c, purified VacA
treated with trypsin for 5 h at
37°C.
[View Larger Version of this Image (46K GIF file)]
; cf.,
Fig. 3, top row). A possible reason for this difference will
be discussed after presenting further data below. As was
seen in the previous deep-etch study of VacA, a second
distinct form of VacA oligomer was also observed (Fig. 2,
fifth row). It appeared relatively "flat" and lacked the
prominent central ring described above. These flat forms
generally represented <10% of the total number of
flower-like molecules present but turned out to be important indicators of the underlying construction of VacA, as
will be elaborated below. The petals comprising such flat
forms were elongated ellipsoids measuring about 6 × 14 nm. These radiated from the center of the complex with a distinct clockwise cant or skew. This same chirality was also
observed in the earlier deep-etch study, although flat
forms were also more commonly seven sided in that study
(Lupetti et al., 1996
; cf., Fig. 3, bottom row).
Fig. 3.
Rotary replicas of
VacA molecules drawn from
a previous study (Lupetti et
al., 1996) in which seven-sided forms predominated. The top row displays whole
flowers, and the bottom row
displays flat forms. Both are
composed of seven radial
subunits but are otherwise
structurally identical to the
six-sided forms shown in Fig. 2.
[View Larger Version of this Image (85K GIF file)]
). To determine whether H. pylori
isolates with type m2 vacA alleles produce flower-shaped
VacA complexes similar to those shown in Fig. 2, culture
supernatants from two isolates with type m2 VacA alleles
(strains 95-54 and 86-338) were prepared for EM as above.
Each of these strains produced immunoreactive VacA
macromolecules that were similar in size to VacA from
strain 60190, based on immunoblot analysis of gel filtration chromatography fractions (not shown). Correspondingly, deep-etch EM of VacA preparations from these
strains yielded images of six-sided flower-shaped molecules (Fig. 2, fourth row). Interestingly, however, flat forms
of VacA were not detected in these preparations.
; Austin
et al., 1991
, 1992
). Western blot assays using anti-HspB
and antiurease sera indicated that these proteins were
present along with VacA in H. pylori broth culture supernatants. HspB and urease eluted from a Superose 6 size
exclusion column in fractions corresponding to a slightly
smaller size than VacA (not shown). Correspondingly, HspB
appeared in deep-etch EMs as 14 × 16-nm barrel-like
molecules, and urease appeared as spherical entities 17-18
nm in diameter (Fig. 2, sixth and seventh rows).
), with platinum deposited from 15° above the horizontal in the
absence of sample rotation to create shadows roughly
3.5× longer than an object is tall (Fig. 4). Based on the observed shadow lengths, HspB barrels stood ~12 nm above
the mica, and urease stood ~15 nm above the mica (Fig. 4,
fourth and fifth rows). These measurements compared favorably with the 17-nm diameter of rotary-replicated urease spheres since platinum coating should add 2-3 nm to
the apparent diameter of all molecules (Heuser, 1989
).
Fig. 4.
Unidirectional shadow-castings of
macromolecules produced by H. pylori 60190. First and second rows: flower forms of VacA, including the rare seven-membered examples
found in current preparations. Third row: Flat
forms of VacA. Fourth row: HspB molecules.
Fifth row: Urease molecules.
[View Larger Version of this Image (168K GIF file)]
), but during prolonged storage it undergoes limited
proteolytic degradation into ~34- and ~58-kD components (Telford et al., 1994a
; Garner and Cover, 1996
). To
determine whether VacA cleavage into ~34 and ~58-kD
fragments was associated with an increased abundance of the flat VacA forms, as claimed in the previous deep-etch study of VacA (Lupetti et al., 1996
), we compared the
ultrastructure of VacA in preparations containing only intact ~90-kD bands with that of preparations consisting entirely of ~34- and ~58-kD VacA cleavage products (the
latter resulting from storage of VacA at 4°C for 2 mo before adsorption to mica, or from treatment with exogenous
trypsin before adsorption to mica) (Fig. 5). In our hands,
neither treatment altered the proportion of intact versus flat VacA oligomers (Fig. 2, third row). Thus, we could not
confirm the previous claim that the proportion of flat forms
was increased by proteolysis (Lupetti et al., 1996
). Instead,
we developed the impression that flat forms tended to
occur in groups near the fractured surfaces of our replicas,
suggesting that they may be artifactual freeze-cleavage
products of intact flowers. Furthermore, when proteolysed
VacA was fractionated on a Superose 6 HR 16/50 gel filtration column, subsequent SDS-PAGE and immunoblotting indicated that the ~34- and ~58-kD fragments remained
together in the same high-molecular mass fractions that
normally contained the intact ~90-kD VacA species. This
demonstrates that the ~34- and ~58-kD domains of VacA
remain associated within the VacA flower, even after proteolysis, and rules out the possibility that flat VacA forms
are oligomers that have lost one or the other of these proteolytic fragments.
). We confirmed this result in
the present study (not shown). To determine whether
acidification of VacA alters its ultrastructure, VacA was
adsorbed onto mica chips at neutral pH in the usual way,
and then the mica was washed for 60 s in a 100 mM glycine
buffer at pH 3.5. This procedure yielded not the usual flowers, but instead relatively discrete clusters of up to 12 separate petals (Fig. 6, first through third rows). When not
too widely separated from each other, the petals in these
complexes radiated from the center with a distinct clockwise cant or chirality, identical to that seen previously in
the flat VacA forms. However, the prominent central rings
that characterize intact VacA flowers were nowhere to be
seen. Importantly, the petals generated by this acid-
induced dissociation appeared to be identical in size and
shape to the individual petals comprising the flat forms of VacA described above. The only difference was that they
occurred in groups of up to 12 petals rather than in groups
of only six (compare Fig. 6, first row, with Fig. 2, fifth row).
Fig. 6.
Acid-induced dissociation of VacA demonstrated in rotary replicas.
First through third rows: intact VacA adsorbed to mica at neutral pH as in Fig. 2 and
then treated with pH 3.0 glycine buffer. This caused the
preadsorbed flowers to
"burst" into astral arrays of
up to twelve petals. Fourth
and fifth rows: VacA acidified to pH 3 before adsorption to mica. This caused
nearly complete splaying of
the flowers (fourth row) or
complete dissociation (fifth
row). Note that the individual 6 × 14-nm petals (the
presumed VacA monomers)
appear slightly curved or bilobed when viewed in isolation (arrow).
[View Larger Version of this Image (204K GIF file)]
Fig. 7.
Glycerol gradient sedimentation of
VacA at neutral and acidic pH. VacA-containing
samples were centrifuged through 10-35% glycerol gradients, as described in the Materials and
Methods. Gradients (5 ml) were fractionated
from the top, and aliquots of each fraction were
resolved on 10% SDS-polyacrylamide gels. VacA was detected by immunoblotting with rabbit anti-VacA serum and enhanced chemiluminescence reagents. Gradients and samples were
at pH 7.5 (A), pH 3 (B), and pH 7.5 after acidification and reneutralization of the sample (C).
The position of standards sedimented in a parallel gradient is shown (bovine serum albumin [4.6 S], catalase [11.2 S], and thyroglobulin [19 S]).
The peak of VacA immunoreactivity corresponds
to ~22 S at pH 7.5 and to ~5 S at pH 3.0. High-
molecular mass aggregates of VacA were detected in the bottom pellet fractions of each of
the gradients.
[View Larger Version of this Image (30K GIF file)]
Fig. 8.
Rotary replica of
reannealed VacA oligomers
after acid-induced dissociation followed by reneutralization. Top row: Examples of complexes that reannealed
into six-sided shapes like the
original flowers (cf. Fig. 2).
Bottom row: Examples of
complexes that assumed a
seven-sided configuration
like those seen in the starting
material of an earlier study
(Lupetti et al., 1996; cf. Fig.
3). Arrowheads indicate examples of incorrect realignment of petals that typify VacA reannealings.
[View Larger Version of this Image (83K GIF file)]
Fig. 9.
Stereo images of two different views of flat VacA molecules. To correspond with Fig. 10, the newly recognized counterclockwise flat forms with visible central rings are labeled as top halves, while the more common clockwise flat forms are labeled as bottom halves. The VacA flowers themselves are labeled as wholes.
[View Larger Version of this Image (103K GIF file)]
Fig. 10.
A structural model of VacA based on the three different deep-etch EM views described in this report (Fig. 9). Right: The
flower view, interpreted to be a dodecamer composed of two hexameric flat forms interlocked face-to-face. Center: The newly recognized hexameric flat form with counterclockwise chirality and a prominent central ring. The visible surface of this flat form corresponds to the outermost visible face of the VacA flower shown at right. Left: The more common flat form with clockwise chirality and no central ring, interpreted to be the opposite view of a VacA hexamer. This visible surface would be sandwiched in the center of the dodecamer and not normally accessible to view.
[View Larger Version of this Image (43K GIF file)]
Discussion
Fig. 11.
Schematic view of how the deposition of platinum on
intact VacA flowers would obscure their chirality. The progressive increase in highlighting is intended to represent increasing
amounts of platinum deposition. This would accentuate the central ring but would largely obscure the cant of the subunits.
[View Larger Version of this Image (35K GIF file)]
). There, the flower was considered to be a single-layered complex composed of six or
seven ~90-kD subunits, each divided into distinct ~34-
and ~58-kD domains, one set of which was thought to give
rise to the central ring and the other to the flat form of
VacA. This interpretation was based on an experiment
in which a preparation of proteolytically nicked VacA
yielded an unusually high proportion of flat forms, which
were designated "processed" forms, implying that they were
derived from flowers that had released the group of subunits that formed the central ring (Lupetti et al., 1996
).
The present work disagrees with that interpretation because it shows no correlation between the degree of VacA
proteolysis and the relative abundance of flat forms. Despite considerable effort to confirm the earlier interpretation, including a thorough examination of VacA preparations that had undergone proteolysis during prolonged
storage at 4°C as well as preparations that had been intentionally proteolysed with exogenous trypsin, no increase in
the relative abundance of flat forms was ever observed.
Furthermore, it became apparent in the present study that
the component petals of the flat forms (especially in the
clockwise views) were identical to the individual petals observed when VacA is dissociated into its component ~90-kD monomers by acidification. This observation alone argues strongly that the flat VacA forms represent six intact ~90-kD subunits arranged in an astral array and thus represent one-half of the complete VacA flower.
), we conclude that most of the observed flat forms
must be artifacts of the EM preparation, resulting from hemisection of intact dodecameric VacA flowers during freeze-fracturing. This would explain why >95% of the observed
flat forms
and all of the ones that were clustered
exhibited a clockwise chirality. Thus, regardless of which side of
an intact VacA flower had adsorbed to mica, its cleavage
during freeze-fracture would invariably leave behind its
bottom hexamer (Fig. 10, left image).
may have resulted from inadvertent exposure to
acidic pH during the purification (Manetti et al., 1995
) or
EM processing.
) and spontaneously reassemble at neutral pH (Hardy et al., 1988
). Curiously, even
though the amino acid sequences of CtxB and EtxB are
~80% identical to each other (Domenighini et al., 1995
),
CtxB disassembles at around pH 3.9, whereas EtxB requires pH 2 to disassemble (Ruddock et al., 1995
). Within
the ~7-nm pentameric B-rings of these enterotoxins, adjacent subunits are held together via several different sorts of hydrophobic interactions, hydrogen bonds, and salt
bridges (Sixma et al., 1993
). Presumably, analogous noncovalent interactions hold the larger VacA oligomers together.
). We
now conclude that in fact a major change in the EM structure of VacA does occur upon acidification and that the
observed dissociation of the VacA oligomer could account, at least in part, for the reported changes in its circular dichroism and fluorescence spectra. We further speculate that acid-induced loosening of the oligomeric VacA
structure could result in increased surface exposure of previously hidden hydrophobic VacA domains. As such, acidified VacA could more readily bind to and/or penetrate
membranes. This may help to explain the observation that
acidification of certain recombinant VacA fragments enhanced their capacity to penetrate lipid vesicle membranes
and form ion-conductive channels (Moll et al., 1995
). Similarly, when exposed to acidic conditions, several other bacterial protein toxins and tumor necrosis factor
are
known to undergo conformational changes that permit them to insert into membranes and form ion-conductive
channels (Boquet and Duflot, 1982
; Hoch et al., 1985
;
Farahbakhsh et al., 1987
; Dumont and Richards, 1988
; Papini et al., 1988
; Milne and Collier, 1993
; Milne et al., 1994
;
Montecucco et al., 1994
; Narhi et al., 1996
).
). Presumably, similar acid activation and
membrane insertion of VacA also may occur within endosomes. Morphologic studies have demonstrated that VacA
is indeed internalized by cells (de Bernard et al., 1995
;
Garner and Cover, 1996
), and VacA-induced vacuolation
of cells apparently depends upon the proper functioning of
endosomal Rabs (Papini et al., 1997
). However, H. pylori
is unique in that it resides in the mucus layer of the human
stomach, where it is exposed to a range of pHs, ranging
from pH 7 at the depths of the mucus layer at the surface
of the epithelial cells to pH 2 at the lumenal surface of the
gastric mucus layer (Quigley and Turnberg, 1987
). Thus,
VacA may well be exposed to acidic pH and disassemble
before contacting or entering its target cells. The capacity
of VacA to disassemble at acid pHs is likely to be an important feature of its activation and mechanism of action.
Received for publication 10 March 1997 and in revised form 17 June 1997.
Address all correspondence to Timothy L. Cover, Division of Infectious Diseases, A3310 Medical Center North, Vanderbilt University School of Medicine, Nashville, TN 37232. Tel.: (615) 322-2035. Fax: (615) 343-6160.We thank Beverly Hosse (Vanderbilt University) for technical assistance with the VacA preparation, Robyn Roth (Washington University) for producing all the deep-etch replicas and for much of the EM, and J. Hiroshi Morisaki (Washington University) for generating the final computer images of individual molecules in Figs. 10 and 11. Special thanks also to Dr. Pietro Lupetti (Department of Evolutionary Biology, University of Siena) for many stimulating discussions and suggestions, and also for providing the replicas that were photographed to generate Fig. 3.
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