FRS Marine Laboratory, PO Box 101, Victoria Road, Aberdeen AB11 9DB, UK1
Author for correspondence: M. Victoria López-Dóriga. Tel: +44 1224 295612. Fax: +44 1224 295620. e-mail: doriga{at}marlab.ac.uk
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ABSTRACT |
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Keywords: Photobacterium damselae subsp. piscicida, fish epithelial cells, invasion efficiency
Abbreviations: EPC, epithelioma papillosum carpio; IE, invasion efficiency
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INTRODUCTION |
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The pathogenesis of P. damselae is poorly understood. It has been demonstrated that the polysaccharide capsular layer has an important role in the virulence of the pathogen (Magariños et al., 1996b ), as also have the extracellular products and iron availability (Magariños et al., 1992
, 1994
). Regarding the interaction of P. damselae with phagocytes, the results have been contradictory. Whilst morphologically intact bacteria within macrophages have been found in vivo (Kubota et al., 1970
; Nelson et al., 1981
; Kusuda & Salati, 1993
; Noya et al., 1995a
, b
), suggesting that P. damselae can survive inside macrophages, in vitro studies (Skarmeta et al., 1995
; Arijo et al., 1998
) have indicated that macrophages from three different fish species were able to kill the bacteria. More recently, Barnes et al. (1999)
have confirmed that this species is unable to respond to oxidative attack such as that experienced during the macrophage respiratory burst. On the other hand, it has been suggested that P. damselae could avoid host defence mechanisms and antimicrobial agents by intracellular survival in non-phagocytic cells (Magariños et al., 1996a
) since it has been demonstrated that this bacterium is capable of invading different fish cell lines (Magariños et al., 1996a
; Yoshida et al., 1997
).
The ability to invade epithelial cells is a key determinant of virulence for several human pathogenic bacteria such as Escherichia coli andYersinia, Salmonella and Shigella species (Galán, 1994 ; Zierler & Galán, 1995
). Amongst fish pathogens, this capacity has been demonstrated for Aeromonas hydrophila (Leung et al., 1996
; Tan et al., 1998
) and Vibrio anguillarum (Wang et al., 1998
). P. damselae is considered weakly or moderately adherent and invasive to various fish cell lines (Romalde & Magariños, 1997
). Moreover, it showed a high binding capacity to fish intestines (Magariños et al., 1996a
). The adherence seemed to be mediated by a protein or glycoprotein receptor of the bacterial cell surface, and the internalization of the bacteria was an actin-microfilament-dependent mechanism (Magariños et al., 1996a
). Although these authors have indicated that P. damselae is able to remain viable inside the cells for at least 2 d, and to spread from cell to cell, it has not been demonstrated that internalization in fish cell lines is a specific process.
This study was carried out to analyse and obtain a better understanding of P. damselae internalization, by studying invasion efficiency (IE), the kinetics of invasion, the role of the capsule, and the effects of heating and exposure to UV light, serum and antiserum on the invasiveness of this species.
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METHODS |
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Tissue culture.
Epithelioma papillosum carpio (EPC) cells were grown in 75 cm2 flasks containing Glasgow modification of Eagles minimal essential medium (G-MEM) (ICN) with 10% fetal bovine serum (FBS, Sigma). In all the experiments, EPC cells were grown to a confluence of 8090% (between 2x106 and 1x107 cells per 25 cm2).
Bacterial hydrophobicity.
The cell surface hydrophobicity of the P. damselae strains used was studied using the salt aggregation test (SAT). The assay was performed essentially as described by Lindhal et al. (1981) . Briefly, serial doubling dilutions of ammonium sulphate were made ranging between 4 M and 0·003 M in 0·002 M sodium phosphate buffer (pH 6·8). To 50 µl of each dilution, 50 µl of bacterial suspension (
1010 c.f.u. ml-1) was added. The lowest concentration at which agglutination occurred was recorded for each strain.
Adherence assay.
Bacteria were grown as indicated above and 25 µl added to each well of a 24-well tissue culture plate containing a sterile glass coverslip seeded with EPC cells. The plates were centrifuged (150 g, 5 min) to achieve contact between bacteria and cells. The infected cultures were incubated at 22 °C from 15 min to 24 h. After incubation, coverslips were washed with PBS (137 mM NaCl, 2·7 mM KCl, 10 mM Na2HPO4 and 1·7 mM KH2PO4, pH 7·2) to remove non-adherent bacteria, fixed with methanol, stained with Giemsa and mounted with 90% glycerol in PBS.
Quantitative invasive assay.
Invasiveness of P. damselae MT1415 was tested and E. coli HB101 (Sigma) a non-invasive strain, was used as a negative control. From an overnight TSB culture, E. coli was inoculated into TSB and grown at 37 °C for 3 h to obtain an exponential-phase culture.
EPC cells were seeded in 75 cm2 flasks and grown until 8090% confluent. New medium was added to the cells, which were then suspended using a scraper. Cells were counted in a counting chamber and distributed in microtubes (1x105 EPC cells per tube) containing 1 ml of G-MEM supplemented with 10% FBS. Serial dilutions of freshly grown, exponential-phase bacteria suspended in PBS were prepared so as to produce m.o.i.s ranging from 0·1 to 106 bacteria per epithelial cell. One hundred microlitres of the bacterial suspensions was added to each tube. Each dilution was prepared in duplicate. After adding the bacteria, the microtubes were centrifuged for 5 min at 150 g to initiate contact between bacteria and epithelial cells. The infected EPC cells were incubated for 2 h, centrifuged and resuspended for 1 h in 1 ml medium containing 100 µg gentamicin (Gibco) ml-1 to kill extracellular bacteria. The infected cells were washed with medium and then lysed with 1 ml 1% Triton X-100 for 10 min. One hundred microlitres of this suspension was serially diluted in PBS and the bacteria were quantified by viable count after growth for 48 h at 22 °C on TSA-2 for P. damselae and 24 h at 37 °C on TSA for E. coli.
To confirm that the conditions used in the antibiotic assay described were sufficient to eliminate the extracellular bacteria, the bactericidal activity of gentamicyn was determined essentially as described by Barnes et al. (1991) , with the following modifications. A single antibiotic concentration (100 µg ml-1) was used in G-MEM. Inocula were prepared by serial tenfold dilution from a stock suspension of 1011 bacteria ml-1 of P. damselae MT1415 to give similar concentrations to those employed in the antibiotic protection assay, ranging from 5 x 1010 to 5x104 bacteria ml-1. The suspensions and antibiotic were incubated for 1 h at room temperature. Following incubation, residual antibiotic was diluted out in fresh TSB-2 prior to determining bacterial viability by plating onto TSA-2.
Study of invasion of EPC cells by P. damselae using fluorescence microscopy.
The technique described by Devrets & Campbell (1991) and Bandín et al. (1995)
was used to differentiate adherent from intracellular bacteria. Bacteria were harvested, washed (2000 g at 4 °C for 15 min), resuspended in PBS and the OD540 adjusted to 1·52·0. The bacteria were then labelled by incubation with 0·1 mg FITC (isomer I, Sigma) ml-1, 0·1 M NaHCO3, pH 9·0 at 22 °C for 60 min. Bacteria were pelleted at 1500 g for 5 min and washed free of unbound FITC with PBS (510 times). After washing, the bacterial concentration was determined in a counting chamber and adjusted to 108109 cells ml-1. EPC cells were seeded in 25 cm2 flasks and incubated at 22 °C until 8090% confluent. Prior to infection, the cells were scraped from the flasks and distributed equally into tubes (1 ml per tube); 25 µl labelled bacteria was then added to each tube. After centrifugation (150 g for 5 min) and gentle resuspension, the infected EPC cells were incubated at 22 °C in a rotary mixer (20 r.p.m.) for various times. At the end of the incubation period, the infected cells were washed three times with PBS (150 g for 5 min, 4 °C) to remove free bacteria, centrifuged and resuspended in 100 µl PBS. Ethidium bromide (Sigma) was then added (500 µg ml-1, final concentration), and after mixing, a 10 µl drop was placed on a glass slide and overlaid with a coverslip.
Preparations were observed with a fluorescence microscope (Leica DM LB). Intracellular bacteria fluoresced green and extracellular bacteria fluoresced orange. The percentage of EPC cells with at least one intracellular bacterium was calculated as the mean of random counts of 100 cells, repeated at least three times. All the assays were carried out in triplicate.
Heat and UV light treatment.
To investigate if invasiveness depended on the viability of P. damselae and/or a heat-labile receptor, bacteria were killed by either heat or UV light. Bacteria grown for 24 h on a TSA-2 plate were treated with UV light for 2 h. For heat treatment, the bacteria were suspended in PBS and heated at 80 °C for 10 min. Three plates of TSA-2 for each treatment were inoculated to confirm the non-viability of the bacteria. After inactivation, bacteria were labelled with FITC and incubated with EPC cells (m.o.i. 25) as indicated above.
Production of sea bass anti-P. damselae antiserum.
Sea bass, 12 kg, were kept in seawater aquaria at 20 °C. Fish were immunized with a formalin-inactivated bacterin made from a 48 h culture of P. damselae MT1415 grown in TSB-2 at 22 °C. The bacterin was emulsified 1:1 in Freunds complete adjuvant. Fish were intramuscularly injected (100 µl), followed by an identical immunization 30 d after initial injection. Sera were collected 14 d after the second immunization and stored at -20 °C until required. Normal serum was collected from non-immunized fish. The agglutinating titres were determined as described by Roberson (1990) . The titre of the antiserum against strain MT1415 was 1:16. No agglutination was detected after incubation of MT1415 with normal serum.
Treatment with normal serum and antiserum.
Heat-inactivation of the sera was carried out at 45 °C for 15 min in order to inactivate complement (Sakai, 1981 ).
Invasion assays were conducted as described above. After FITC-labelling and washing, the bacteria were suspended in PBS to about 3x108 ml-1. Aliquots (100 µl) were placed into five microcentrifuge tubes (in triplicate) and incubated with 500 µl PBS as control, sea bass normal serum, heat-inactivated normal serum or heat-inactivated antiserum for 10 min at room temperature. After centrifugation (1500 g, 5 min), bacteria were washed and resuspended in PBS. Bacteria were added to EPC (m.o.i. 1519) and incubated for 2 h. Visualization of intracellular bacteria was carried out as above by the fluorescence method.
Transmission electron microscopy.
The techniques described by Watanabe et al. (1988) for rabbit platelets and by Gutenberger et al. (1997)
for trout leucocytes were used. EPC cells obtained as described above were infected with bacteria. After centrifugation (150 g for 5 min) and gentle resuspension, the infected EPC cells were incubated for 19 h at 22 °C in a rotary mixer (20 r.p.m.), washed three times with PBS (900 g for 5 min) to remove non-attached bacteria and pelleted. The pellet was resuspended in 2% glutaraldehyde buffered with 0·05 M PIPES (Hayat, 1986
) at pH 7·2 and fixed for 1 h at room temperature. After washing twice with 0·025 M PIPES and centrifugation at 230 g for 10 min, two drops of 2% agarose (agarose type VII, low gelling temperature <30 °C) maintained at 37 °C were added. The cells were centrifuged at 230 g for 5 min at room temperature and then left on ice until the agarose gelled. The gel was cut into small pieces (1 mm2), postfixed with 1% aqueous osmium tetroxide for 1 h, and left overnight at room temperature in 2% aqueous uranyl acetate. Dehydration in an acetone series was followed by embedding in araldite (Durcupam ACM) using propylene oxide as an intermediate solvent. Ultrathin sections (7080 nm) were obtained with an LKB Ultratome III, stained on the grid with Fahmys lead citrate (Lewis & Knight, 1977
) and examined with a Hitachi H-300 electron microscope.
Statistical analysis.
All the results were analysed by applying a unifactorial ANOVA test and probabilities of <0·05 were considered significant. The data are presented as means±SD.
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RESULTS |
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Kinetics of bacterial invasion
The bactericidal test confirmed that the gentamicin concentration and incubation time used for the invasion assay were sufficient to kill the extracellular bacteria. Bacterial IE was calculated as: (number internalized c.f.u. at the end of the assay/starting inoculum) x100. Invasion efficiency of P. damselae MT1415 was tested at different m.o.i.s, from 0·16 to 1·6x106 bacteria per EPC cell (Fig. 1a). Maximum IE (2·77%) was observed at an m.o.i. of 0·162 and was reduced to about 1% at m.o.i.s of 1·6 and 16·0. At higher m.o.i.s, IE values decreased gradually. The non-invasive control E. coli HB101 was tested over a similar range of m.o.i.s and the maximum IE was 0·0038% (data not shown).
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The number of internalized c.f.u. per EPC cell resulting from varying the m.o.i. (Fig. 1c) increased slowly for the first four m.o.i.s and then there was a sharp increase up to 6·5 bacteria per EPC cell at m.o.i. 1620. This value doubled at m.o.i. 16000 and thereafter remained constant at m.o.i.s
1·6x104.
Quantification of P. damselae internalization by the fluorescence method
The fluorescence staining assays confirmed the presence of intracellular micro-organisms (Fig. 2). By using this method, it was possible to quantify the percentage of EPC cells infected over time, as well as the intensity of infection (i.e. number of bacteria per infected EPC cell) over time.
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Hydrophobicity and invasion of the virulent and avirulent strains
Non-capsulated P. damselae strain EPOY-8803-II aggregated with a lower (0·25 M) concentration of ammonium sulphate than the capsulated strain MT1415 (>4 M). For invasion assays, EPC cells were infected with equivalent bacterial concentrations (108 bacteria ml-1, m.o.i.
15) of the virulent MT1415 and non-virulent EPOY-8803-II strains, incubated for 1 and 3 h and observed by fluorescence microscopy. There were no significant differences between the percentage of EPC cells invaded by the two strains, either after 1 h (MT1415, 37·8±1·8%; EPOY-8803-II, 38·83±1·04%) or 3 h (MT1415, 49·3±5·1%; EPOY-8803-II, 49·0±0·9%) incubation.
Effect of heat, UV light, serum and antiserum on bacterial invasiveness
After heat and UV light treatments, no viable bacteria could be detected on TSA-2 plates, confirming complete inactivation of the bacteria. Invasiveness of heat-inactivated bacteria was greatly reduced (9·3±1·5% EPC cells invaded) compared with the non-inactivated bacteria (52·2±4·0% EPC cells invaded). However, bacteria inactivated by UV light were still able to invade up to 44·8±1·5% of EPC cells, which was not significantly (P>0·05) different from the non-treated viable bacteria.
Capsulated bacteria incubated with heat-inactivated normal serum invaded a similar percentage of EPC cells (47·5±4·4%) as the control (bacteria incubated with PBS) (49·2±2·0%). However, when bacteria were incubated with fresh normal serum, the percentage of EPC cells infected was significantly (P<0·05), but not greatly, reduced (36·0±1·5%). Incubation of the bacteria with heat-inactivated sea-bass antiserum provoked a significant (P<0·05) decrease in the number of epithelial cells with intracellular bacteria (24·5±1·0%).
Ultrastructure of P. damselae infection
Ultrastructural studies of EPC cells infected with P. damselae provided information on the alterations which occurred both in host cells and bacteria. EPC cells infected with bacteria were incubated for 1, 3, 5, 7 and 9 h; non-infected EPC cells were used as control. No changes in cell morphology occurred in the control cell cultures over the experimental period (data not shown).
After 1 h infection, both extra- and intracellular bacteria could be seen. Extracellular bacteria were in close association with the plasma membrane (Fig. 4a). EPC cells showed cytoplasmic extensions around the bacteria which were interpreted as the first steps in the engulfment process (Fig. 4b
). The intracellular bacteria were always situated within membrane-bound vacuoles (Fig. 4b
, c
) and no evidence of membrane disintegration was found. Vacuoles with multiple bacteria were observed (Fig. 4c
) which may have been the result of several bacteria being engulfed at the same time or of vacuole fusion. Five hours after infection, most bacteria were located within large membrane-bound vacuoles and no evidence of bacteria free in the cytoplasm was seen.
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DISCUSSION |
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Magariños et al. (1996a) indicated this species was weakly or moderately invasive. These authors tested various fish cell lines at an m.o.i. of 100 and found that up to 103 bacteria were recovered from EPC cells after the antibiotic assay. Unfortunately, the concentration of neither the bacteria or the fish cells was stated in this report so it is not possible to compare the results directly with the present data. The invasive properties of a species depend greatly on the bacterial strain and cell lines used, as has been demonstrated for Salmonella, where the IE varied between
6 and 38% depending on the cell lines and the bacterial strain tested (Mills & Finlay, 1994
). On the other hand, we have demonstrated that, for this species, m.o.i. has a clear effect on the number of bacteria that invade the cells. IE of P. damselae was maximal at the lowest m.o.i. (0·16), whereas the number of internalized bacteria and the number of bacteria per epithelial cell reached saturation at higher m.o.i.s (
1·6x104). This relation between m.o.i. and invasion should be borne in mind in future studies on P. damselae invasiveness since the value of m.o.i. chosen represents a compromise between number of internalized bacteria and IE.
The maximum IE observed for P. damselae in the present study represents 2% of the initial inoculum, a percentage significantly lower than those indicated for some human invasive bacterial pathogens, such as Salmonella typhimurium (Huang et al., 1998 ) or Yersinia enterocolitica (Small et al., 1987
), which showed IEs of 48·9% and 21%, respectively. However, the level found here for P. damselae is higher than those reported for some other invasive species, such as Campylobacter jejuni (0·10·2%) (Konkel et al., 1993
), and similar to the enteroinvasive E. coli 11 (2·9%) (Small et al., 1987
). The present study also showed that the induced uptake of P. damselae by the EPC cells was not a non-specific property of the cell line, since the cells were not invaded by the non-invasive E. coli HB101.
More intracellular organisms and higher numbers of bacteria per epithelial cell were recorded as the m.o.i. increased, until a saturation level was reached at high m.o.i.s (1·6x104). These results suggest that internalization of P. damselae by EPC cells is a process mediated by receptorligand interactions, since this type of process is characterized by saturability (García-Peñarrubia et al., 1992
). Both epithelial cells and bacteria seem to be involved in the internalization process. The host cell plays an active role since the internalization of the bacteria is inhibited by cytochalasin D (Magariños et al., 1996a
), indicating that it is dependent upon host actin microfilaments. Moreover, the ultrastructural analysis by transmission electron microscopy described here provides evidence that P. damselae is ingested into vacuoles, possibly by an endocytic process, in a similar way to pathogens such as Salmonella, Shigella spp. and Yersinia (Finlay & Falkow, 1988
). On the other hand, heat-killed bacteria were unable to invade the epithelial cells, whilst the UV-light-inactivated bacteria retained their invasive capabilities. This suggests that engulfment does not require P. damselae to be viable, but integrity of its surface components is necessary to permit interactions between the bacteria and the surface of the host cells. These results agree with those of Magariños et al. (1996a)
, who found that adhesive capacities are affected by heat and sugars, and suggested that adherence may be mediated by a glycoprotein of the bacterial or host cell surface.
Once internalized by non-phagocytic cells, micro-organisms have different strategies to survive within the host cells. Some bacteria, such as Shigella spp. (Sansonetti et al., 1986 ) and Rickettsia (Heinzen et al., 1993
), escape from the vacuole to multiply in the cytoplasm and later infect adjacent cells. However, there are numerous bacterial species that remain inside the vacuoles of the epithelial cells throughout infection. Species such as Salmonella and Yersinia (Finlay & Falkow, 1988
; Janda et al., 1991
), Haemophilus influenzae (Virji et al., 1991
) or group B streptococci (Rubens et al., 1992
) are included in this group. P. damselae did not seem to escape from the vacuoles. At no time during infection were bacteria observed free in the cytoplasm. Instead, they were found within large cytoplasmic vacuoles where they remained viable for several hours. The intracellular time period seems to be dependent on the cell line used and assay conditions since Magariños et al. (1996a
) found that P. damselae remained inside CHSE-214 cells for at least 2 d, whilst in the present study the bacteria were liberated from the EPC cells 79 h after infection.
Some invasive bacteria replicate inside the host cells (Finlay & Falkow, 1988 ). However, during the present study, examination of a large number of electron micrographs failed to show evidence of intracellular multiplication of P. damselae. Data from the fluorescence assay indicated an increasing number of intracellular bacteria per cell at longer incubation times, which could be due either to continuous invasion or to replication of the organisms inside the EPC cells. However, when the extracellular bacteria were eliminated from the medium there was no further increase in the number of intracellular bacteria, which supports the electron microscopic observations that P. damselae does not seem to replicate inside the EPC cells. Bacterial replication seemed to occur once the bacterium had left the host cell and was observed extracellularly 9 h after infection.
The virulence factors that contribute to IE of epithelial cells by P. damselae are unknown. Significant differences in IE between non-capsulated and capsulated P. damselae strains were not observed, although the surface hydrophobicity of the avirulent non-capsulated EPOY-8803-II strain is strong according to the criteria proposed by Santos et al. (1990) , whilst the virulent capsulated strain MT1415 is not hydrophobic. Similar results were found by Magariños et al. (1996a)
who studied the adherence to tissues of capsulated (virulent) and non-capsulated (avirulent) strains of P. damselae. The lack of effect of the bacterial capsule on adherence or invasion has been reported in other Gram-negative bacteria, such as H. influenzae (Lipuma & Gilsdorf, 1987
; Roberts et al., 1984
) and enterotoxigenic E. coli (Guerina et al., 1983
). However, studies on the role of bacterial capsules in adherence or invasion to host cells are contradictory. It has been postulated that a capsule may reduce adhesiveness in several species, such as E. coli (Runnels & Moon, 1984
), H. influenzae (St Geme & Falkow, 1991
; Virji et al., 1991
), Actinobacillus pleuropneumoniae (Jacques et al., 1991
) and Pasteurella multocida (Jacques et al., 1993
). On the other hand, it has been found that the E. coli capsule may promote adherence (Davis et al., 1981
; Chan et al., 1982
). Recent studies with H. influenzae (St Geme & Cutter, 1996
) have suggested that the level of encapsulation, and not the presence of capsule by itself, influences the adhesive interactions of the organism with its host cells. In P. damselae, the level of encapsulation seems also to be important, since although the constitutive capsule of virulent strains does not interfere with adhesion, a thicker capsular material decreases adherence to host tissues (Magariños et al., 1996b
). Since both capsulated and non-capsulated strains of P. damselae appear to be able to invade fish epithelial cells, the virulence of the capsulated bacteria cannot be explained solely on the basis of their ability to invade host cells.
Incubation of the bacteria prior to invasion with fresh normal sea bass serum slightly, but not significantly, reduced the percentage of EPC cells invaded by the encapsulated strain, whilst incubation with heat-inactivated normal serum had no effect on invasiveness. Although this could suggest a certain degree of inhibition by the complement of fish serum on capsulated bacteria, the percentage of infected epithelial cells was still high. It has been demonstrated that bacterial capsules confer resistance to bactericidal activity of serum (Amaro et al., 1994 ; Daly et al., 1996
), including that of P. damselae (Arijo et al., 1998
; Magariños et al., 1996b
). This slight reduction in invasiveness with fresh normal fish serum may be a consequence of some bacteria with a thinner capsule being killed by the action of complement. Incubation with heat-inactivated antiserum against strain MT1415 had a significant effect on invasion, indicating that antibodies reduce the invasiveness of the bacteria, presumably by blocking the surface receptors involved in adhesion and/or invasion. The effect of antiserum is certainly specific as heat-inactivated normal serum did not decrease invasiveness and did not agglutinate the bacteria as did the antiserum. Thus, nonspecific interactions with fish serum proteins have no effect on bacterial invasiveness.
The presence of intracellular bacteria in host cells has been interpreted as a mechanism to avoid phagocytosis and host immune responses, reducing their effectiveness and favouring the spread of infection (Virji et al., 1991 ; Magariños et al., 1996a
; Galán, 1994
; Amaro et al., 1994
; Daly et al., 1996
). As Virji et al. (1991)
pointed out, bacteria do not need intracellular replication, only the ability to enter and survive inside the host cells and to exit. The present data show that P. damselae can invade fish epithelial cells, remain intracellular for a few hours, leave the host cells by lysing them and replicate extracellularly. As the capsule confers resistance to complement-dependent killing (Margariños et al., 1996b
; Arijo et al., 1998
), the intracellular environment may be more important to escape contact with phagocytes. Although some studies have indicated that P. damselae survives inside macrophages (Kubota et al., 1970
; Nelson et al., 1981
; Kusuda & Salati, 1993
; Noya et al., 1995a
, b
), Skarmeta et al. (1995)
and Arijo et al. (1998)
found that fish macrophages have the ability to kill the bacteria, and Barnes et al. (1999)
have recently confirmed that P. damselae does not have adaptive defences against the bactericidal activities of macrophages. Since macrophages are able to kill P. damselae, the invasion of epithelial host cells may avoid, or at least delay, the contact between bacteria and macrophages, so contributing to the advance of disease.
Currently, there are no commercially available vaccines showing any degree of protection against pasteurellosis (Magariños & Romalde, 1997 ). Furthermore, chemotherapeutic failure is widely reported. This may partially reflect the growing body of evidence suggesting an intracellular phase to the life-cycle of this organism (Yoshida et al., 1997
; Magariños et al., 1996a
; Magariños & Romalde, 1997
). The present data lend further support to this contention, demonstrating that internalization is a specific process and not passive uptake by the cell line. This intracellular phase, coupled with other factors such as the capsule (Arijo et al., 1998
), may aid the pathogen in avoiding the hosts cellular and humoral defences. Identification of the components and mechanisms involved in this internalization process may provide alternative targets for vaccination. There is evidence for activation of the host cells actin system and a role for glycoproteins (Magariños et al., 1996a
). It may be that a type III secretion system or similar is involved. Work towards characterizing these components is continuing in our laboratory.
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ACKNOWLEDGEMENTS |
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Received 6 July 1999;
revised 6 September 1999;
accepted 17 September 1999.
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