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Infect Immun, February 1998, p. 549-557, Vol. 66, No. 2
Dipartimento di Biologia Cellulare e dello
Sviluppo, Fondazione Istituto Pasteur-Cenci Bolognetti,
Università di Roma "La Sapienza," 00185 Rome, Italy
Received 8 July 1997/Returned for modification 2 September
1997/Accepted 11 November 1997
We have constructed and analyzed a group of Shigella
flexneri 5 auxotrophic mutants. The wild-type strain M90T was
mutagenized in genes encoding enzymes involved in the synthesis of (i)
aromatic amino acids, (ii) nucleotides, and (iii) diaminopimelic acid. In this way, strains with single (aroB, aroC,
aroD, purE, thyA, and
dapB) and double (purE aroB, purE
aroC, purE aroD, purE thyA) mutations
were obtained. Although the Aro mutants had the same nutritional
requirements when grown in laboratory media, they showed different
degrees of virulence in vitro and in vivo. The aroB mutant
was not significantly attenuated, whereas both the aroC and
aroD strains were severely attenuated.
p-Aminobenzoic acid (PABA) appeared to be the main
requirement for the Aro mutants' growth in tissue culture. Concerning
nucleotides, thymine reduced the pathogenicity, whereas adenine did
not. However, when combined with another virulence-affecting mutation,
adenine auxotrophy appeared to potentiate that mutation's effects.
Consequently, the association of either the purE and
aroC or the purE and aroD mutations
had a great effect on virulence as measured by the Sereny test, whereas
the purE aroB double mutation appeared to have only a small
effect. All mutants except the dapB strain seemed to move within a Caco-2 cell monolayer after 3 h of infection.
Nevertheless, the auxotrophs showing a high intracellular generation
time were negative in the plaque assay. Knowledge of each mutation's
role in attenuating Shigella strains will provide useful
tools in designing vaccine candidates.
Shigella flexneri is a
human pathogen that provokes bacillary dysentery by invading the
colonic mucosa (20). The pathogenic process encompasses
several steps: (i) bacterial entry into colonic epithelial cells; (ii)
intracellular multiplication; and (iii) intraintercellular spreading,
which allows bacteria to infect neighboring cells (for reviews see
references 9, 15, and 39).
Localized lesions at the colonic mucosa level result from cell
destruction and inflammation (27). All of these events
ultimately induce the symptoms of dysentery, which include fever and
stools containing mucus and blood (15). The molecular and
cellular basis of pathogenesis has been studied by using limited
laboratory animal models and in vitro-grown mammalian cell lines which
are susceptible to infection (16).
Entry into epithelial cells occurs by an engulfment of the host cell
membrane at the interaction points with bacteria (1). The
membrane rearrangements are associated with the formation of actin
polymerization foci which are close to the sites of bacterium-cell contact. Components of both bacteria and host cells actively
participate in this process. On the host cell side, several proteins
such as plastin (1), the small GTPase Rho (2),
and the proto-oncoprotein pp60 (10) have been found to be
involved in this step. On the bacterial side, determinants necessary
for mediating S. flexneri uptake are localized on a 31-kb
fragment of a large plasmid (28, 44). Invasion plasmid
antigens IpaB, IpaC, and IpaD are the real effectors of the entry
phenotype (30).
After being internalized, S. flexneri lyses the phagosomal
vacuole and multiplies within the cytoplasm of infected cells
(43). Intracellular shigellae express and secrete the
plasmid-encoded IcsA, which allows the spreading of bacteria within the
cytoplasm and dissemination into adjacent cells (7, 25).
IcsA, located at one pole of the bacterium, governs S. flexneri movement by interacting with F-actin and vinculin
(12, 13, 49).
While several studies address the processes of bacterial penetration
and movement, scant information is available regarding the
intracellular multiplication process and particularly which metabolites
required for replication are present, in limited amounts, in the
cytoplasm of infected cells. Nevertheless, in recent years, studies on
vaccine candidate construction have indicated that mutations in
biosynthetic pathways of both aromatic amino acids and nucleotides may
alter the intracellular replication of shigellae (4, 21, 22, 35,
36). Lindberg and coworkers showed that S. flexneri 2a
microorganisms harboring an aroD mutation are attenuated not
only in vitro but also in vivo (21, 22). Moreover, Noriega
and coworkers also demonstrated that S. flexneri aroA
mutants are affected in virulence (35). These two Aro
mutants showed a reduced intracellular growth as demonstrated in the
cell culture invasion assay. Aro mutants are auxotrophic for aromatic amino acids and other molecules such as p-aminobenzoic acid
(PABA) and dehydrobenzoic acid. Virulence phenotypes of these two
mutants appear to be similar, but since they have not been directly
compared, it is still unclear if mutations in aroA and
aroD induce equivalent attenuation.
On the other hand, S. flexneri 2 Pur These observations suggest that some products of the Aro pathway are
present in host cell cytoplasm and tissues in a limited amount and that
their availability may affect intracellular bacterial growth.
Concerning purines, the findings presented by different groups at times
appear to be contradictory.
The purpose of our study was to further investigate intracellular
multiplication through the analysis of a group of auxotrophic mutants
of the S. flexneri 5 wild-type strain M90T, with the aim of
identifying those metabolites necessary to cell invasion whose absence
could influence the intracellular behavior of shigellae and ultimately
their degree of virulence.
Bacterial strains and media.
The bacterial strains used are
listed in Tables 1 and
2. Bacteria were routinely cultured in
tryptic soy broth (BBL, Becton Dickinson and Company, Cockeysville,
Md.) or brain heart infusion (Difco Laboratories, Detroit, Mich.). The
ability of bacteria to bind the pigment Congo red was assessed by using
tryptic soy broth plates containing 1.5% agar and 0.01% Congo red. M9
salts (32) were used for preparing minimal medium. Carbon
sources were added to a final concentration of 0.2% with the addition of nicotinic acid (10 µg/ml) to support the growth of shigellae. M9
was supplemented with various nutrients required by the different auxotrophic mutants. Briefly, aroC, aroB, and
aroD mutants grew on M9 medium with PABA and
3,4-dehydroxybenzoate (both to a final concentration of 100 µg/ml)
plus tryptophan, phenylalanine, and tyrosine (all at 40 µg/ml).
thyA, purE, and dapB mutants required thymine (50 µg/ml), adenine (50 µg/ml), and diaminopimelic acid (100 µg/ml), respectively. Kanamycin, spectinomycin, tetracycline, and ampicillin were added at 50, 100, 10, and 100 µg/ml,
respectively.
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Intracellular Multiplication and Virulence of
Shigella flexneri Auxotrophic Mutants
ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
mutants
(not characterized at the genetic level) have been found not to be
attenuated either in vitro in HeLa cells (23) or in vivo in
a guinea pig model. This model measures the ability of virulent
shigellae to induce keratoconjunctivitis when they are inoculated in
the conjunctival sac (Sereny test) (47). By contrast, a
recent study by Noriega et al. has shown that the guaB-A
deletion mutant, unable to synthesize guanine nucleotides, is severely
impaired in intracellular multiplication (36). Concerning
pyrimidines, S. flexneri Y thymine auxotrophs (thyA) do not produce a cytopathic effect on a confluent
HeLa cell monolayer and have low levels of virulence in vivo (4, 38). These auxotrophic mutants have been used as vaccine
candidates. In particular, to obtain a strong virulence attenuation,
either the 
aroA, the guaB-A, or the
thyA mutation (affecting the intracellular proliferation)
has been combined with an icsA deletion (altering intracellular-intercellular spreading) (35, 36, 53).
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
TABLE 1.
Bacterial strains and relevant characteristics
TABLE 2.
S. flexneri 5 strains and
relevant characteristics
Genetic procedures and strain construction. Generalized transduction with bacteriophage P1 was performed as described by Miller (32). Depending on the marker transduced, transductants were selected on media supplemented with antibiotic or nutrients.
(i) Construction of ZB2100 (M90T
thyA::Tn10), ZB2101 (M90T
purE::Tn10), ZB2102 (M90T
aroC::Tn10), ZB2103 (M90T
aroD::Tn10), and ZB2104 (M90T
dapB-Km).
Each insertion, namely,
thyA::Tn10,
purE::Tn10,
aroC::Tn10,
aroD::Tn10, and dapB-Km,
was transduced to M90T, using Escherichia coli 
2904
(thyA::Tn10), E. coli NK6051
(purE::Tn10), S. flexneri 2 SFL148 (aroC::Tn10), S. flexneri Y SF114 (aroD::Tn10), and
E. coli 
159 (dapB-Km) as the respective
donors. When Tn10 insertion was used as a selectable marker,
transductants were isolated for tetracycline resistance, while
kanamycin resistance, encoded by a cartridge inserted into
dapB in 159, provided the means for positive selection in
the construction of the M90T dapB mutant. The
transductants obtained were checked for the acquired auxotrophies: thymine for thyA, adenine for purE, PABA,
3,4-dehydroxybenzoate, tryptophan, phenylalanine, and tyrosine for Aro,
and diaminopimelic acid for dapB. ZB2101 (M90T
purE::Tn10), ZB2102 (M90T
aroC::Tn10), ZB2103 (M90T
aroD::Tn10), and ZB2104 (M90T
dapB-Km) were selected to be analyzed in the virulence
assays.
(ii) Construction of ZB2111 (M90T aroB-Ap).
A
fragment from nucleotides 580 to 1151 of S. flexneri 5 aroB was amplified by PCR using two primers derived from the
corresponding E. coli aroB sequence (for
5'-TAATGAACCAGCT; for 3'-CCATGTAACCAAT) (31). The fragment was cloned in the SmaI
site upstream of the lacZ gene in the suicide plasmid vector
pLAC1 (5), thus obtaining plasmid pZB211. pZB211 was
maintained in E. coli SM10 
pir (48) and then transferred by conjugation into M90T-Sm (5). The
transconjugants were selected on plates containing streptomycin and
ampicillin. Since pZB211 did not replicate in S. flexneri,
the ampicillin-resistant clones arose through homologous recombination
between the aroB fragment carried by pZB211 and the
corresponding chromosomal aroB. The insertion of pZB211 into
the aroB locus was confirmed by PCR and Southern blot
analysis with the 478-bp AvaII fragment (from positions 611 to 1089) as a probe. The resulting strain ZB2111 was checked for the
acquired auxotrophies on minimal medium.
(iii) Construction of ZB2106 (M90T purE).
To
obtain a purE mutant, the S. flexneri
purE::Tn10 strain (ZB2101) was submitted to
selection on fusaric acid as described by Bochner et al.
(8). This experimental procedure selects strains subject to
the Tn10 excision and which have become sensitive to
tetracycline. ZB2101 (purE::Tn10)
derivatives were assumed to have simultaneously lost the
Tn10 insertion and the purE gene, thus becoming
tetracycline sensitive and auxotrophic for adenine. About 20 tetracycline-sensitive, fusaric acid-resistant, and adenine auxotrophic
strains were chosen for further virulence analysis. ZB2106 (M90T
purE) was submitted to molecular and phenotypic assays as
detailed in Results and then used as recipient in the construction of
double mutants. PCR analysis performed with 3' and 5' probes derived
from the E. coli purE locus sequence confirmed that the
purE gene was deleted in ZB2106.
(iv) Construction of the double mutants ZB2107 (M90T
purE thyA::Tn10), ZB2108 (M90T
purE aroC::Tn10), ZB2109 (M90T
purE aroD::Tn10), and ZB2112 (M90T
purE aroB-Ap).
Using ZB2106 (M90T
purE) as a recipient and 2904 (E. coli
thyA::Tn10), SFL148 (S. flexneri 2 aroC::Tn10), SF114 (S. flexneri Y aroD::Tn10), and ZB2111
(M90T aroB-Ap), respectively, as donors, the ZB2107 (M90T
purE thyA::Tn10), ZB2108 (M90T
purE aroC::Tn10), ZB2109 (M90T
purE aroD::Tn10), and ZB2112 (M90T
purE aroB-Ap) mutants were constructed by P1 generalized
transduction as described above.
Virulence assays. (i) HeLa cell culture conditions. Cells were routinely maintained in minimal essential medium (MEM; GIBCO-BRL) supplemented with fetal bovine serum (HyClone Laboratories, Inc., Logan, Utah) at a concentration of 5%. Twenty-four hours before both multiplication and plaque assay, MEM was supplemented, when necessary, with either thymine, diaminopimelic acid, PABA, or dehydroxybenzoate at a final concentration of 100 µg/ml.
(ii) Infection of HeLa cells. The HeLa cell invasion assay was performed as described by Hale et al. (16).
(iii) Intracellular multiplication of bacteria in HeLa cells. Multiplication of bacteria in HeLa cells was assayed as described previously (43), with minor modifications. Nonconfluent monolayers of HeLa cells (8 × 104 to 9 × 104/ml) on 35-mm-diameter dishes were inoculated with bacteria suspended in 2 ml of MEM at a multiplicity of infection (MOI) of 100, centrifuged, and incubated for 40 min at 37°C to allow bacterial entry. Plates were washed three times with phosphate-buffered saline (PBS) and covered with 2 ml of MEM containing gentamicin (50 µg/ml). This point was taken as time zero (T0). Incubation lasted for 5 or 8 h in different experiments. Two plates were removed at each time (T1, T2, T3, T4, and T5 or T1, T3, T6, and T8). One plate was washed three times with PBS and Giemsa stained to calculate the percentage of infected HeLa cells. The other plate was washed five times with PBS to eliminate viable extracellular bacteria. Cells were trypsinized, counted, and then lysed with 0.5% sodium deoxycholate in distilled water. Dilutions of this suspension were plated onto brain heart infusion agar supplemented with various nutrients required by the different auxotrophic mutants.
When infection lasted 12 h, the invasion assay procedure was slightly modified. To allow Shigella entry, dishes containing cells and bacteria were incubated for 2 h without centrifugation. After five washes, cells were covered with 2 ml of MEM supplemented with gentamicin. This was taken as T0. Only two times (T1 and T12), were evaluated. Since only a few cells were found infected after 12 h, we recorded the number of bacteria in the monolayer. Intracellular survival in the presence of cefotaxime was analyzed by modifying the experimental procedure of the invasion assay. Briefly, HeLa cell monolayers were infected with bacteria; after 2 h postinfection in the presence of gentamicin, two plates for each strain were removed and treated as described above. This was taken as T0. The other plates were washed five times with PBS and covered with 2 ml of MEM supplemented with gentamicin and cefotaxime (300 µg/ml). Cells were incubated in the presence of cefotaxime for 6 h. After this time, the plates were treated to quantify surviving bacteria.(iv) Plaque assay. The plaque assay was carried out as originally described by Oaks et al. (37).
(v) Sereny test. The keratoconjunctivitis assay in guinea pigs was performed as originally described (47), using two challenges, 108 and 109 CFU. The results were evaluated as suggested in a recent study (17).
Phase-contrast micrographs and labeling of bacteria. Bacteria growing to mid-exponential phase were washed and fixed to polylysine-treated coverslips. IcsA was detected by using a rabbit polyclonal antibody directed against IcsA followed by a rhodamine-conjugated goat anti-rabbit immunoglobulin G secondary antibody as recently described by Egile et al. (11).
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RESULTS |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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S. flexneri auxotroph construction.
The S. flexneri auxotrophic strains harboring a mutation in either one of
the metabolic pathways which lead to the synthesis of (i) aromatic
amino acids (M90T aroB-Ap, M90T
aroC::Tn10, and M90T
aroD::Tn10), (ii) adenine (M90T
purE::Tn10), (iii) thymine (M90T
thyA::Tn10), and (iv) diaminopimelic
acid (M90T dapB-Km) were constructed as described in
Materials and Methods. To obtain mutants having more than one
auxotrophy, we decided to combine the purE mutation with
each of the mutations mentioned in categories i and iii. Therefore,
ZB2101 (M90T purE::Tn10) was assessed
in the plaque assay and in the Sereny test (at a challenge of
109 CFU) and gave positive results in both tests. To
achieve the deletion of the purE locus, ZB2101 was submitted
to fusaric acid selection and ZB2106 (M90T purE) was
chosen for further analysis as detailed in Materials and Methods.
ZB2106 (M90T purE) produced plaques similar in size and
number to those of the parent strain (ZB2101) and gave positive results
in the Sereny test. Using ZB2106 (M90T purE) as
recipient, ZB2107 (M90T purE
thyA::Tn10), ZB2108 (M90T purE
aroC::Tn10), ZB2109 (M90T purE
aroD::Tn10), and ZB2112 (M90T purE
aroB-Ap) were constructed by P1 generalized transduction (see
Materials and Methods).
Intracellular multiplication kinetics of ZB2101 (M90T
purE::Tn10), ZB2106 (M90T purE),
ZB2102 (M90T aroC::Tn10), ZB2103 (M90T
aroD::Tn10), ZB2111 (M90T aroB-Ap),
ZB2108 (M90T purE aroC::Tn10),
ZB2109 (M90T purE aroD::Tn10), and ZB2112
(M90T purE aroB-Ap).
To evaluate the real rate of
intracellular multiplication in each invaded cell, experimental
conditions that minimize intercellular spreading were adopted. Thus, by
lowering the number of cells (maintaining the MOI of 100), a scattered
monolayer consisting of groups of three to four cells was obtained.
purE strain (and that of the parent
purE::Tn10 strain) was similar to that
of M90T except for the peak of the maximum number of intracellular
bacteria that seemed to be delayed (Fig. 1A). As reported for the
Aro strains, the double mutants ZB2108 (M90T
purE aroC::Tn10), ZB2109 (M90T
purE aroD::Tn10), and ZB2112 (M90T
purE aroB-Ap) had different capabilities to proliferate
intracellularly. ZB2112 (M90T purE aroB-Ap) behaved like
ZB2111 (M90T aroB-Ap), whereas ZB2108 (M90T purE
aroC::Tn10) and ZB2109 (M90T purE
aroD::Tn10) (Fig. 1B) multiplied at a very
low rate. Usually, the invasion cycle of the wild-type strain on HeLa
cell monolayers does not last more than 6 to 7 h of infection
(43). After this time, only a few bacteria are seen in the
infected cells. In contrast, Giemsa staining of HeLa cells infected
with either ZB2108 (M90T purE
aroC::Tn10) or ZB2109 (M90T purE
aroD::Tn10) (Fig.
2) showed that their cytoplasm was full
of bacteria even after 8 h of invasion. At an MOI of 10 instead of
100, the behavior of these strains did not change and their
intracellular multiplication kinetics remained alike.
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Intracellular growth of ZB2100 (M90T
thyA::Tn10), ZB2104 (M90T
dapB-Km), and ZB2107 (M90T purE
thyA::Tn10).
ZB2100 (M90T
thyA::Tn10), ZB2107 (M90T purE
thyA::Tn10), and ZB2104 (M90T
dapB-Km) did not appear to survive in host cells, making
it impossible to evaluate the number of intracellular bacteria per
infected cell. Figure 1C shows the number of bacteria in the monolayer.
Although the number of intracellular ZB2100 (M90T
thyA::Tn10) and ZB2107 (M90T
purE thyA::Tn10) cells decreased
considerably after 3 h postinfection, the bacteria were still
observable within the cytoplasm of infected cells after this time (Fig.
2); they had a characteristic shape (long filaments). This form arose
from the limiting availability of thymine in the infected cell
cytoplasm. In fact, bacteria grown to mid-exponential phase in a medium
unsupplemented by thymine exhibited this characteristic shape, as shown
in Fig. 3A.
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dapB-Km) showed intracellular multiplication
kinetics similar to that of ZB2100 (M90T
thyA::Tn10) and ZB2107 (M90T
purE thyA::Tn10) (Fig. 3), even
though it did not produce filaments, and bacteria appeared engulfed in
vesicles or in protrusions of the HeLa cell membranes (Fig. 2).
To test whether the impairment in intracellular multiplication
observed with these three auxotrophs was due to low levels of thymine
and diaminopimelic acid, HeLa cells were treated with either thymine or
diaminopimelic acid as detailed in Materials and Methods. The invasion
assays were performed in the presence of these substances. The addition
of diaminopimelic acid to the cell medium restored the ability of
ZB2104 (M90T dapB-Km) to grow intracellularly, whereas
thymine restored a correct shape of intracellular ZB2100 (M90T
thyA::Tn10) and ZB2107 (M90T
purE thyA::Tn10) along with their
ability to proliferate (data not shown).
The generation times of all mutants were calculated after 3 and 6 h of infection and are shown in Table 3.
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Survival of the mutants after 12 h of infection and in the presence of cefotaxime. Only strains that had an intracellular multiplication kinetics similar to that of the wild-type strain were able to survive after 12 h of infection, as shown in Table 4.
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Plaque assay and intercellular movement.
The plaque assay
reflects the ability of shigellae to spread within a cell monolayer and
to damage host cells. The results of this process are detected as a
plaque, i.e., a zone of dead cells destroyed by bacterial infection
(37). As expected, ZB2111 (M90T aroB-Ap) and
ZB2112 (M90T purE aroB-Ap) were positive in this assay.
ZB2103 (M90T aroD::Tn10), at an MOI of
10, was seen to form tiny plaques. All other mutants were negative
(Table 3).
purE
thyA::Tn10), and ZB2104 (M90T
dapB-Km). Additionally, when the cell medium was
supplemented with PABA, ZB2102 (M90T aroC::Tn10), ZB2103 (M90T
aroD::Tn10), ZB2108 (M90T purE
aroC::Tn10), and ZB2109 (M90T purE
aroD:Tn10) gave a positive result in this test. The
number and size of plaques were similar to those of the wild-type
strain.
To determine whether the intercellular movement of the auxotrophic
mutants was impaired, we assessed their capability to colonize the
Caco-2 islets. S. flexneri strains enter the Caco-2 islets only through the basolateral pole of these cells (33). Only bacteria able to move intracellularly and from cell to cell can reach
the center of the infected islet without passage in the extracellular
medium. All mutants tested except one were able to move in the Caco-2
islets to various degrees (data not shown). The only exception was the
dapB mutant. Since IcsA is polarized on the bacterial
cell surface, we also checked its distribution on the filament surface
of ZB2100 (M90T thyA::Tn10) by
immunostaining IcsA with a polyclonal antibody raised against it. After
2 h of bacterial growth in thymine-free medium, different forms of
these bacteria coexisted. The immunofluorescence analysis revealed that most of the bacteria producing filaments still polarized IcsA on their
surface (Fig. 3B).
Sereny test analysis.
Some of the mutations analyzed in
this study have been already tested in other Shigella spp.
or serotypes. SL114 (S. flexneri Y
aroD::Tn10) and an S. flexneri 2 thymine auxotrophic mutant do not give a positive
result in the Sereny test (21, 38). In this study, the
Sereny test was performed with two challenges (108 and
109 CFU). When 109 bacteria were inoculated
(Table 3), ZB2101 (M90T purE::Tn10), ZB2106 (M90T purE), ZB2111 (M90T aroB-Ap), and
ZB2112 (M90T purE aroB-Ap) induced a keratoconjunctivitis
similar to that provoked by M90T. The only exception was ZB2112 (M90T
purE aroB-Ap), which induced the appearance of
symptoms about 18 h later than did the wild type. The intensity of
the inflammatory reaction was weak. The symptoms induced by ZB2101
(M90T purE::Tn10) and ZB2106 (M90T purE) were delayed, but the intensity of the
keratoconjunctivitis was the same as that observed with M90T.
purE), ZB2111 (M90T aroB-Ap), and ZB2112 (M90T
purE aroB-Ap) was delayed for about 18 h, and the
severity of conjunctivitis was mild (rating 2). The results are
summarized in Table 3.
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DISCUSSION |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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In this study, we have constructed and analyzed a group of S. flexneri 5 M90T auxotrophic mutants that harbor one or two mutations in the metabolic pathways which lead to the synthesis of aromatic amino acids, nucleotides, and diaminopimelic acid (aroB, aroC, aroD, purE, thyA, dapB, purE aroB, purE aroC, purE aroD, and purE thyA). These mutants proliferate poorly in media where nutrients are present in limited amounts. Since shigellae meet similar conditions in host tissues during natural infection, these strains were supposed to be potentially impaired in intracellular multiplication.
The Aro mutants show different virulence attenuated phenotypes. Various Aro mutants selectively inactivated in either one or two steps of aromatic amino acid biosynthesis have been obtained by different groups (19, 22, 35, 51). The Aro mutants are auxotrophs for aromatic amino acids, PABA (a precursor of folic acid), and dehydroxybenzoic acid (a precursor for the iron-binding enterochelin).
We constructed three Aro mutants, each carrying a mutation in aroB, aroC, or aroD. Although all of these mutants show the same nutritional requirements in laboratory media, they have different degrees of virulence in vitro as well as in vivo. aroB encodes 3-dehydroquinate (DHQ) synthase, which converts 3-deoxy-D-arabino-heptulosonate 7-phosphate to DHQ. DHQ production is an early reaction in chorismate biosynthesis. S. flexneri aroB shows levels of virulence similar to those of the wild-type parent strain when assessed in tissue culture virulence tests. It proliferates in host cells with a generation time close to that of M90T and is positive in the plaque assay. Like other Aro mutants, M90T aroB needs PABA and aromatic amino acids to grow in culture media. Eukaryotic cells do not synthesize PABA and need exogenous folic acid that usually is incorporated as folate into folyl polyglutamate (41). Folate polyglutamate is subject to a certain degree of turnover in cultured human cells (18). Hence, intracellular aroB mutants might scavenge some intermediate metabolite of folate turnover to be used in chorismate biosynthesis to overcome the step controlled by the aroB product. Additionally, 3,7-dideoxy-D-threo-hepto-2,6-diulosonic acid, which is a precursor of DHQ, can be converted chemically to DHQ without any enzymatic reaction (3). M90T aroD shows characteristics close to those described by Lindberg et al. (21, 22) and Karnell et al. (19) for S. flexneri Y aroD and S. flexneri 2a aroD, respectively (Table 3). M90T aroD exhibits an intracellular generation time which is slightly greater than that of M90T (126 ± 9.9 min versus 75 ± 5.1 min after 6 h of infection), and its intracellular survival is similar to that of M90T. At an MOI of 10, M90T aroD is positive in the plaque assay, though the zones of cell necrosis are smaller than those induced by the parent strain. aroD encodes DHQ dehydratase, which introduces the first double bound in the aromatic ring, thus converting DHQ to 3-dehydroshikimate. Several intermediate metabolites separate 3-dehydroshikimate from the final product, chorismate. Therefore, intracellular aroD could utilize some intermediate metabolite of folate turnover to synthesize chorismate, as suggested above for the aroB strain. M90T aroC is severely affected in intracellular multiplication, as shown by (i) its very high intracellular doubling time (178 ± 16.9 min) and (ii) its ability to survive intracellularly in the presence of cefotaxime. aroC encodes the last enzyme involved in chorismate biosynthesis. This enzyme converts 5-enolpyruvoylshikimate-3-phosphate to chorismate by introducing the second double bound in the aromatic ring. In contrast to the other two Aro mutants, which harbor mutations in genes encoding enzymes involved in early steps, this strain is mutagenized in the last reaction yielding chorismate. Consequently, it cannot use eukaryotic cell metabolites to synthesize this molecule. Therefore, in the presence of low amounts of chorismate and/or PABA, its proliferation within host cells is greatly impaired. The S. flexneri 2 aroA mutant created by Noriega et al. (35) was described as exhibiting a reduced intracellular growth and eliciting only a transient and slight inflammatory response in the Sereny test. The aroA product is the 5-enolpyruvoylshikimate-3-phosphate synthase involved in the penultimate reaction of the chorismate production. The analysis of both mutants, S. flexneri 5 aroC and S. flexneri 2 aroA, suggests that mutations in the terminal steps of the chorismate biosynthesis pathway confer a serious virulence attenuation. Our results indicate PABA as a key requirement for intracellular shigellae. All Aro simple and double mutants showing virulence attenuation in vitro can be restored to full virulence by treating tissue culture cells with PABA. Since folate is a normal constituent of cell culture media, this finding also suggests that shigellae cannot or may less easily utilize folate than PABA. Results obtained in vivo reflect those observed in vitro. However, PABA and Aro products appear to be less available in host tissues than in infected cytoplasms. In fact, the aroB mutant provokes a moderate inflammatory response when administered at both low and high dose levels, while aroD and aroC strains do not elicit keratoconjunctivitis in the experimental conditions used. This observation has also been confirmed by Bacon et al., who demonstrated that Salmonella PABA auxotrophs do not grow in minimal medium supplemented with peritoneal fluid (6).Thymine but not adenine auxotrophy lowers virulence levels.
The purE locus includes the purE1 and
purE2 genes, which encode AIR
(5'-phosphoribosyl-5-aminoimidazole) carboxylase, which is an
intermediate step in IMP biosynthesis. S. flexneri purE mutants do not grow in laboratory media in the absence of adenine, but
they proliferate intracellularly at the same rate as the parent strain.
They are positive in the plaque assay and induce a strong inflammatory
reaction in the Sereny test when administered at high doses
(109 CFU). At a low inoculum (108 CFU), the
reaction is mild and delayed. Nucleotides present in the growth medium
may be utilized as nucleic acid precursors by bacteria only if they are
dephosphorylated to nucleosides by periplasmic nucleotidases
(54). Such an activity could reduce the intracellular multiplication of purE mutants. Since this is not the case
(as demonstrated through tissue culture multiplication assay), it is
conceivable that salvage pathways enable shigellae to utilize preformed
nucleobases or nucleosides available within eukaryotic cytoplasm. This
issue is not confirmed for Shigella guanine auxotrophs since, as described by Noriega et al. (36), mutants unable
to synthesize guanine (harboring guaB-A deletion) show a
dramatic reduction of virulence. In our laboratory, a purHD
deletion mutant unable to synthesize hypoxanthine exhibits the same
virulence attenuation pattern (6a). In contrast to these
results, a Listeria monocytogenes adenine auxotrophic strain
has been found to be severely attenuated (26). These data
indicate that guanine but not adenine availability is a key factor
influencing the virulence of shigellae. We realized that by combining
adenine auxotrophy (purE) with one of the Aro mutations
(in this way obtaining strains harboring either purE
aroB, purE aroC, purE aroD mutations), virulence attenuation was potentiated. This is not an unexpected result
since one of the final reactions yielding IMP synthesis requires
10-formyltetrahydrofolate, which is produced from PABA. Therefore, the
addition of an Aro mutation strengthens the effect of the
purE deletion.
purE thyA mutants were restored to the ability to elicit
a positive plaque assay by adding thymine to the tissue culture cell.
This result suggests that this molecule is also essential to full
virulence.
Introduced mutations selectively alter the interactions of
shigellae with eukaryotic cells.
Main virulence-associated
phenotypes such as invasion (34) and spreading
(14) are related to the bacterial cell division process.
Hence, shigella mutants having high generation times will be supposedly
altered in phenotypes which rely on cell division. aroC,
purE aroC, and purE aroD mutants exhibiting
high generation times (Table 3) are negative in the plaque assay.
However, within 3 h of infection these strains move from the
peripheral cells to those centrally located through the Caco-2 islets.
This is apparently in contrast to the finding of the plaque assay. We observed that the generation time of the auxotrophic mutants usually increases starting from 3 to 6 h of infection. This growth
retardation could be due to the fact that the intrabacterial stocks of
nutrients are exploited. Thus, as the generation time increases,
bacteria move slowly, as shown by (i) the number of infected HeLa
cells, which does not change after 3 h of infection (data not
shown), and (ii) the inability to form observable plaques of lysis. As confirmation to this hypothesis, the aroD mutant, which has
a slightly higher replication rate than the wild type, still
disseminates within HeLa cell tissue cultures and thus is positive in
the plaque assay.
|
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ACKNOWLEDGMENTS |
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We thank S. Stocker, R. Curtiss III, and C. Richaud for providing strains. We are also pleased to acknowledge P. Sansonetti's laboratory team for helpful discussion and K. Pepper for critical reading of the manuscript.
This work was supported by an EC biotechnology program (BIO2-CT92-0134) and by a WHO/GPV program (V27/181/79). A. Cersini benefited from a fellowship by Fondazione Istituto Pasteur-Cenci Bolognetti of Rome.
| |
FOOTNOTES |
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* Corresponding author. Mailing address: Dipartimento di Biologia Cellulare e dello Sviluppo, Fondazione Istituto Pasteur-Cenci Bolognetti, Università di Roma "La Sapienza," via degli Apuli 1, 00185 Rome, Italy. Phone: (39-6) 49917579. Fax: (39-6) 49917594. E-mail: bernardini{at}axcasp.caspur.it.
Editor: J. R. McGhee
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REFERENCES |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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