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Previous Article | Next Article 
Infection and Immunity, September 2001, p. 5943-5948, Vol. 69, No. 9
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.9.5943-5948.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Isolation and Characterization of a Vibrio
vulnificus Mutant Deficient in Both Extracellular
Metalloprotease and Cytolysin
Jong-Jin
Fan,
Chung-Ping
Shao,
Ya-Chi
Ho,
Chun-Keung
Yu, and
Lien-I
Hor*
Department of Microbiology and Immunology,
College of Medicine, National Cheng-Kung University, Tainan 701, Taiwan, Republic of China
Received 5 March 2001/Returned for modification 10 May
2001/Accepted 19 June 2001
 |
ABSTRACT |
We isolated a Vibrio vulnificus mutant that was
deficient in both metalloprotease and cytolysin by allelic exchange.
The virulence of this mutant in mice and its cytotoxicity for HEp-2
cells were comparable to those of the wild-type strain, indicating that
neither factor was essential for these properties. The cytolysin, but not the protease, seemed to be important for causing damage in the
alimentary tract of the mice.
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TEXT |
Vibrio vulnificus,
a gram-negative estuarine bacterium, causes wound infections and
septicemia in humans, mostly in immunocompromised people and those with
underlying conditions such as hemochromatosis, liver cirrhosis, and
alcoholism (2, 3, 5, 23). Infection is usually acquired
via direct contact or the gastrointestinal (GI) route; in both cases,
skin lesions with ulcer and edema are common (5, 12, 32).
Strains of V. vulnificus secrete a variety of products that
have been implicated in bacterial virulence and pathogenesis, including
capsular polysaccharide (34), cytolysin (7,
16), metalloprotease (protease) (15, 19),
phospholipases (31), and siderophores (25).
The purified protease of V. vulnificus has been shown to
increase vascular permeability and induce edema by activating the
plasma kallikrein-kinin cascade (18, 21, 22) and to cause
hypodermic hemorrhage (20). It also facilitates bacterial
acquisition of iron by digesting heme proteins, transferrin and
lactoferrin (24). The cytolysin, a pore-forming cytotoxin and hemolysin (13), is lethal to mice at a submicrogram
level (26). It damages mast cells, resulting in release of
histamine (36), and causes hypotension, tachycardia
(14), and skin (9) and pulmonary
(26) damage in animals. Collectively, the cytolysin and
the protease are thought to be important for the pathogenesis of
V. vulnificus. The presence of cytolysin in V. vulnificus-infected mice (10) and the detection of
anticytolysin antibodies in sera from mice and a human that survived
V. vulnificus disease (8) further support the
role of cytolysin in disease development.
Genes encoding the protease (4) and cytolysin
(35) of V. vulnificus have been cloned, and
isogenic mutants deficient in either gene product have been isolated by
an allelic exchange technique (29, 33). Although purified
cytolysin and protease exhibited a variety of biological activities
that seemed to be detrimental to the animals, elimination of either
factor did not attenuate the pathogenicity in mice, as assayed with
several animal models (29, 33). In fact, the
protease-deficient (PD) mutant was even more virulent than the
wild-type strain in mice challenged orally (29). As
mentioned above, both the cytolysin and the protease are able to
increase vascular permeability and cause tissue damage, which may
enhance bacterial invasiveness. Therefore, deficiency in either factor
may not be sufficient to reduce the bacterial virulence, since
compensation of the other factor may occur. We therefore reasoned that
elimination of both factors may be necessary for attenuation of
bacterial virulence. To test this hypothesis, we generated a double
mutant deficient in both the cytolysin and protease and compared its
cytotoxicity for cultured epithelial cells and its virulence and
potential to cause tissue damage with those of both the wild-type
strain and single mutants deficient in either protease or cytolysin.
Bacterial strains and plasmids.
The V. vulnificus
and Escherichia coli strains and the plasmids used in this
study are listed in Table 1. All strains
were routinely grown in Luria-Bertani (LB) medium at 37°C with
aeration.
Cloning of the vvhA gene.
Recombinant clones
containing sequences of the cytolysin gene, vvhA, were
identified in a V. vulnificus gene library (4) by colony hybridization (1, 28). The probe (Fig.
1A), which was derived from the known
vvhA sequence (35), was labeled with [
-32P]dCTP by random priming with a kit
(Megaprime DNA labeling system; Amersham, Little Chalfont, United
Kingdom) using a PCR product as the template. Among the identified
clones, one exhibited hemolysis of murine red blood cells and was shown
to contain both vvhA and vvhB (35)
by comparing the restriction pattern of the insert with that derived
from the published restriction map of this locus (35). A
SalI-BamHI fragment containing vvhA,
vvhB, and the flanking sequences was then excised from the
recombinant plasmid of this clone and inserted into pUC19 to create
pFJ004.
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FIG. 1.
Detection of deletion in vvhA in the
chromosome of V. vulnificus. (A) Restriction map of the
insert in pFJ004, which was used to construct V.
vulnificus mutants FJ201 and FJ202. The deletion (white bar),
the probes used in colony (probe 1) and Southern hybridization (probe
2), and the PCR primers used in detecting the deletion in the mutants
are indicated. S, SalI; C, ClaI; H,
HpaI; B, BglII; Bm, BamHI.
(B) Southern hybridization of the ClaI digests of the
plasmid or chromosomal DNA fractionated by electrophoresis on a 1.2%
agarose gel. Lanes: 1, pCVD442; 2, YJ016; 3, FJ008 (YJ016 integrated
with pFJ006); 4, FJ201; 5, FJ202; M, molecular size standards.
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Isolation of V. vulnificus cytolysin-deficient (CD)
and protease- and cytolysin-deficient (double-deficient [DD])
mutants.
V. vulnificus mutants with disruptions in
vvhA and in both vvhA and the protease gene
(vvp) were isolated from clinical strain YJ016 and its PD
mutant (CP080), respectively, by allelic exchange. CP080, which
contained a 426-bp deletion in vvp, was isolated by allelic
exchange as described previously for isolating another PD mutant
(29).
To introduce an in-frame deletion in vvhA, an
HpaI-HpaI fragment (792 bp) was removed from the
vvhA gene in pFJ004 (Fig. 1A) to generate pFJ005. Correct
deletion was confirmed by nucleotide sequence determination. The whole
insert of pFJ005 was then subcloned into pCVD442 (6) to
generate pFJ006. pCVD442 is a suicide plasmid containing the
sacB gene of Bacillus subtilis which allows
positive selection with sucrose for loss of the vector. pFJ006 was
transferred from SM10
pir to either YJ016 or CP080 by
conjugation. The transconjugants, which had the plasmid integrated into
the chromosome via homologous recombination, were selected by
ampicillin (100 µg/ml) and polymyxin B (50 U/ml) and tested for
sensitivity to 10% sucrose. One of the sucrose-sensitive
transconjugants was grown in LB medium with 10% sucrose overnight and
spread onto a 10% sucrose-containing LB plate for selecting the
sucrose-resistant clones, which were cured of the plasmid via a second
homologous recombination. The resultant strains were further tested for
ampicillin sensitivity. Some of the sucrose-resistant,
ampicillin-sensitive strains were then screened by PCR with a pair of
primers (Fig. 1A) flanking the deletion for those that had the deletion
in vvhA and, therefore, gave rise to a shorter product.
The presence of the vvhA deletion in the mutants was
confirmed by Southern hybridization (1, 28) with a probe
derived from the vvhA gene (Fig. 1A). As shown in Fig. 1B, a
deletion of approximately 0.8 kb was detected in both the CD mutant,
FJ201, and the DD mutant, FJ202. The colonies of the CD and DD mutants were as opaque as those of the parent strains, indicating that both
were encapsulated.
Protease and cytolysin activities in the culture supernatant.
The protease and cytolysin activities in the culture supernatant were
assayed as described previously (29). Briefly, protease activity in bacterial culture supernatants was assayed with azocasein, and the amount of digested azocasein which was not precipitated by
3.2% trichloroacetic acid was measured as optical density at 450 nm
(OD450). Cytolysin activity was assayed based on
its ability to lyse the murine blood cells (0.9% in phosphate-buffered
saline [PBS]). The level of hemolysis was estimated by measuring the optical density at 545 nm (OD545) of the
supernatant after pelleting of the unlysed cells and cell debris by
centrifugation. Cytolysin activity was expressed as
[(OD545 of specimen/OD545
of complete hemolysis)] × 100.
As expected, the DD mutant exhibited neither protease nor cytolysin
activity, while the PD and CD mutants expressed strong cytolysin and
protease activities, respectively (Fig.
2). On the other hand, the cytolysin
activity of the wild-type strain reached a maximum that was only
one-half of that of the PD mutant at 4 h of growth and then
declined rapidly when the protease activity was increased (Fig. 2).
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FIG. 2.
Protease and cytolysin activities in the culture
supernatants of various V. vulnificus strains. Bacteria
were grown at 37°C after a 1:100 dilution of an overnight culture in
fresh medium. The culture supernatant was then collected at intervals,
and the protease and cytolysin activities were determined
(n = 3).
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Virulence in mice.
Six- to eight-week-old C3H/HeNCrj mice
purchased from the animal center of College of Medicine at the National
Cheng-Kung University were used to determine the virulence of the
various V. vulnificus strains. The mice were infected either
by intraperitoneal (i.p.) injection or by force-feeding. For infection
by i.p. injection, mice were either untreated or pretreated with 5 mg
of iron dextran per mouse by intramuscular injection 2 h before
challenge. The animals were then given a 10-fold serially diluted
bacterial suspension in PBS, and mortality was monitored 48 h
postinfection. For infection by force-feeding, each mouse was fed by
intragastric intubation with 500 µl of a 10-fold serially diluted
bacterial suspension in PBS, and the mortality was recorded 72 h
after challenge. To enhance their susceptibility to V. vulnificus, the force-fed animals were pretreated with 3.75 mg of
cyclophosphamide (Sigma, St. Louis, Mo.) per mouse by i.p. injection
72 h before challenge in addition to iron dextran pretreatment as
described above (11). The animals also fasted for 12 h, starting from 8 h before till 4 h after the feeding of
bacteria. The dose lethal to 50% of the mice
(LD50) of each strain was calculated by the
method of Reed and Muench (27).
As shown in Table 2, the
LD50s of all the mutants were comparable to that
of the wild-type strain in mice challenged by i.p. injection, whether
the animals were iron overloaded or not. On the other hand, in mice
challenged by force-feeding, the PD mutant appeared to be more virulent
than the wild-type strain. Specifically, the LD50
of the PD mutant was sevenfold less than that of the wild-type strain.
This finding agreed with our previous report (29). At
least two lines of evidence suggest that an increase in virulence in
the absence of protease may be associated with increased amounts of
some other bacterial factors. First, we observed that a 9-h culture
supernatant of the PD mutant exhibited more protein bands than that of
the parent strain in sodium dodecyl sulfate-polyacrylamide gel
electrophoresis (unpublished data). Second, we demonstrated that the
cytolysin activity in the culture supernatant of the PD mutant was
twofold higher and sustained much longer than that of the parent strain
(29). Surprisingly, the LD50s of the
CD and DD mutants were not remarkably increased and were only
approximately four- to fivefold higher than that of the wild-type
strain. The virulence of the CD and DD mutants suggested that
cytotoxicity was not required for bacterial virulence in mice or,
alternatively, that there is another unidentified cytotoxic factor(s)
in the mutants.
Cytotoxicity assay.
Our results prompted us to determine
whether other cytotoxic factors were present. Cytotoxicity of the
various V. vulnificus strains was determined with HEp-2
cells, a human laryngeal carcinoma cell line. The cells were maintained
in Earle's minimal essential medium (MEM) (Gibco BRL Life Technologies
Inc., Gaithersburg, Md.) containing 10% fetal calf serum
(Biological Industries, Kibbutz Beit Haemek, Israel) and
40 µg of gentamicin (Gibco BRL Life Technologies) per ml.
Cytotoxicity was assayed after treatment of cells with bacterial
culture supernatant, which was sterilized by filtration through a
0.45-µm-pore-size membrane filter, or bacterial suspension. HEp-2
cell suspension (0.2 ml) was plated at a density of 3 × 105/ml in each well of a 24-well tissue culture
plate coated with 0.1% bovine serum albumin, and the cells were grown
at 37°C to confluence. The cell monolayer was washed and then added
with 180 µl of Earle's MEM. In one experiment, bacterial culture
supernatant collected from a 4-h culture in LB medium was added in 20 µl to the cell monolayer in the well. In the other experiment, the
monolayer was infected with 20 µl of washed bacteria (suspended in
PBS) at a multiplicity of infection (MOI) of 0.1, 1, or 10. After
incubation at 37°C for 3 h, the cytotoxicity was determined by
measuring the activity of lactate dehydrogenase (LDH), a cytosolic
enzyme released upon cell lysis, in the supernatant. LDH activity was assayed with a commercial kit (CytoTox 96 nonradioactive cytotoxicity assay; Promega) and was expressed as [(activity of monolayer treated with sample 
activity of that treated with vehicle)/(LDH
activity of monolayer completely lysed by 1% Triton X-100 activity of that treated with vehicle)] × 100.
Table 3 shows that the culture
supernatant of only the PD mutant was cytotoxic to the HEp-2 cells.
Disruption of the cytolysin gene in the PD mutant abolished the
cytotoxicity of the culture supernatant (compare the DD mutant with the
PD mutant), indicating that the cytolysin was the only cytotoxin
secreted. Little cytotoxicity was detected in the 4-h culture
supernatant of the wild-type strain. This was not surprising, because
the cytolysin activity declined rapidly to the basal level when the
protease was produced (Fig. 2B).
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TABLE 3.
Cytotoxicity of culture supernatant and bacterial
suspension of various V. vulnificus strains for HEp-2 cells
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On the other hand, whole cells of all the mutants as well as the
wild-type strain exhibited cytotoxicity for the HEp-2 cells in a
dose-dependent manner (Table 3), indicating that another cytotoxin(s)
might exist in this organism. This factor(s) may not be secreted into
the medium, at least not to a detectable level, upon bacterium-host
cell interaction, because the conditioned medium harvested from the
infected cells was not cytotoxic (data not shown). In addition,
UV-killed bacteria of all strains were not cytotoxic (data not shown),
suggesting that cytotoxicity may be mediated by an energy-dependent
mechanism which is likely activated upon contact with the host cells.
It is intriguing that the LB medium resulted in a higher level of
cytotoxicity than the culture supernatants of the wild-type strain and
CD mutant (Table 3). Because strains producing the protease (wild-type
and CD mutant) had a lower cytotoxicity than those deficient in the
protease (PD and DD mutants) or the LB medium alone, it is suspected
that the protease may degrade some of the toxic components in the LB
medium. Alternatively, the protease may act directly on the cells via
some unknown mechanism to protect them from death.
Tissue damage.
The roles of the protease and cytolysin in
causing damage of the GI tract were examined after infection of mice
with the various strains by force-feeding. Mice (n = 3)
pretreated with cyclophosphamide and iron dextran were challenged with
1.5 × 107 bacteria per mouse by
force-feeding as described above. Two of those challenged by the
wild-type strain, three of those challenged by the PD mutant, one of
those challenged by the CD mutant, and none of those challenged by the
DD mutant died within 24 h after infection. No diarrhea was
observed in either the dead or the surviving mice. The alimentary
tract, from stomach to rectum, was removed and examined immediately
after death or 24 h postinfection. Macroscopically, severe GI
congestion and hemorrhage, particularly in the upper intestine, were
observed with the wild-type strain or the PD mutant (including in the
mouse that survived the infection). In contrast, in mice infected with
the CD or DD mutant, whether they died or survived infection, mild
congestion was occasionally observed. The severity of the GI lesions
was correlated with the mortality rate for each strain.
Excised portions of stomach and small intestine were fixed in 10%
buffered-formalin, embedded in paraffin, sliced into 4-µm sections,
and stained with hematoxylin-eosin for histological examination. No
microscopic lesions were observed in the sections of the stomach
examined. However, various pathological manifestations were seen in the
intestines of the challenged mice. Mice infected with the wild-type
strain had a severe necrotizing enteritis characterized by mucosal and
submucosal congestion, shortening of villi, sloughed and necrotic
epithelial cells with condensed or pyknotic nuclei, and
hypercellularity in the lamina propria (Fig.
3). Infiltration of inflammatory cells
was not present, which should be due to the pretreatment with
cyclophosphamide. Congestion and hemorrhage were more severe in mice
challenged with the PD mutant than in mice infected with the wild-type
strain. No remarkable pathological change, except for a very mild,
occasion congestion, was present in mice infected with the CD or DD
mutant (Fig. 3). Damage of the intestine, therefore, appeared to be
associated with the amounts of cytolysin produced.
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FIG. 3.
Micrographs of upper intestines of mice challenged by
force-feeding with the wild-type strain (B), the PD mutant (C), the CD
mutant (D), and the DD mutant (E). Mice inoculated with PBS were used
as the negative control (A). Note the sloughed and necrotic epithelial
cells with condensed and pyknotic nuclei (arrowheads) and
hypercellularity and congestion in lamina propria (B and C). Intestinal
tissues from mice infected with the CD or DD mutant appear normal.
Hematoxylin-eosin stain was used. Magnification, ×400.
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Conclusions.
A number of conclusions can be drawn from this
study. First, neither the protease nor the cytolysin of V. vulnificus was essential for the virulence in mice, particularly
in those challenged by i.p. injection, because mutants deficient in
either one or both factors were as virulent as the wild-type strain.
Second, cytolysin was the only cytotoxin secreted, because disruption
of the cytolysin gene in the PD mutant abolished the cytotoxicity of
the culture supernatant. However, there was probably another factor(s)
present that enabled the DD mutant to lyse the epithelial cells upon
bacterium-cell interaction. Third, the cytolysin was more potent than
the protease in destruction of the intestine, because the wild type and
the PD mutant, but not the CD and DD mutants, resulted in remarkable tissue damage. The damage probably accounts for the slightly higher mortality rates in mice challenged orally with the wild type and the PD
mutant than in those challenged with the CD and DD mutants.
V. vulnificus is a highly invasive pathogen, being able to
reach the bloodstream and cause septicemia via translocation across the
intact intestinal wall. However, how the organism crosses the
epithelial wall is not known. Our unpublished observation showed that
this organism could hardly invade the epithelial cells. Therefore, one
possibility is that the organisms spread to the bloodstream via open
wounds caused by the bacterial products, as our data showed that the
cytolysin caused remarkable damage to the enterocytes. Alternatively,
the organisms may invade through the M cells, which are specialized
epithelial cells lining the intestinal tract. A number of bacteria have
been shown to use the M cells as an invasion route to enter the host
(30). The fact that the CD and DD mutants were still
invasive, lethal to mice, and cytotoxic strongly suggests the presence
of some unidentified cytotoxin(s). Identification and characterization
of the additional cytotoxin(s) would be crucial for unraveling the
invasion mechanism of V. vulnificus.
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ACKNOWLEDGMENTS |
This work was supported by grants DOH 87-HR-606 from the National
Health Research Institute and NSC 89-2320-B-006-018 from the National
Science Council, Taiwan, and a summer research grant from
Schering-Plough Limited for Ya-Chi Ho.
We are grateful to H. M. Sheu and K. C. Huang for their
valuable comments.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology and Immunology, College of Medicine, National Cheng-Kung University, Tainan 701, Taiwan, Republic of China. Phone:
886-6-2353535, ext. 5635. Fax: 886-6-2082705. E-mail:
h061453{at}mail.ncku.edu.tw.
Editor:
A. D. O'Brien
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Infection and Immunity, September 2001, p. 5943-5948, Vol. 69, No. 9
0019-9567/01/$04.00+0 DOI: 10.1128/IAI.69.9.5943-5948.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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