INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Most pathogens enter the body through mucosal surfaces, and the development of vaccines protective at such sites should be a very effective means of preventing a wide range of infectious diseases (4). Moreover, vaccines that can be administered by the oral or nasal route would not necessitate the professional health care infrastructure required for injectable preparations and may offer an inexpensive and convenient way of vaccination, limiting the risk for cross-contamination by needles. In addition, they are expected to induce less adverse effects (36). One approach for inducing efficient local immune responses relies on the development of live bacterial carriers. Attention in this area, has focused mainly on attenuated pathogenic vectors such as Salmonella, Bordetella, Vibrio, and Mycobacterium strains for the delivery of heterologous antigens to mucosal sites (1, 3, 10, 11, 19, 29). One of the drawbacks of such systems is the need to reduce the pathogenicity of the live carrier through the use of recombinant DNA techniques or classical genetics (33). This attenuation may impair their immunogenicity and raises questions about the safety of the final vector, especially when it is destined for immunodeficient individuals. Commensal bacteria, such as lactic acid bacteria, offer an original alternative as antigen delivery vehicles, as they are generally recognized as safe (17, 26 35). Moreover, their large-scale production is quite easy and inexpensive. The noncolonizing gram-positive bacterium Lactococcus lactis has been used successfully to induce secretory and protective systemic responses against tetanus toxin (TT) after intranasal or intragastric immunization (21, 28). In this respect, Lactobacillus strains which are able to persist in the intestinal tract for several days after administration may be particularly interesting for the mucosal presentation of antigens (18). In addition, specific members of this genus exert a probiotic, i.e., health-promoting, effect linked to their immunostimulation property and capacity to regulate the endogenous microflora (8, 13, 14, 15, 20, 21).

We have previously constructed recombinant Lactobacillus plantarum strains (NCIMB8826) producing different levels of the C fragment of TT (TTFC) intracellularly. These strains obtained by transformation with recombinant plasmids carrying the TTFC genetic determinant were shown to be immunogenic by the subcutaneous route (24; P. Chagnaud, M.-C. Geoffroy, C. Grangette, H. Müller-Alouf, N. Reveneau, D. Raze, and A. Mercenier, unpublished data). In the present study, we address the important issue as to whether these recombinant L. plantarum strains can be delivered by a mucosal (intranasal) route for induction of both mucosal and systemic immune responses against TTFC and of protection against the lethal effect of TT.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacterial inocula. Two recombinant L. plantarum NCIMB8826 TTFC-producing strains were used in this study. They were obtained by electroporation with a plasmid carrying the TTFC-encoding gene under the control of a constitutive (p_ldh) or inducible (p_nisA) promoter, pMEC4 (erythromycin resistance) or pMEC46 (chloramphenicol resistance), respectively (24; Chagnaud et al., unpublished). A control strain harboring the nonexpressing plasmid pTG2247 (chloramphenicol resistance) was used as a negative control (7). Bacteria were grown in MRS broth (Difco, Detroit, Mich.) containing the appropriate antibiotic, erythromycin or chloramphenicol, at a final concentration of 5 or 10 µg per ml, respective. An overnight culture was used to inoculate fresh medium at a 1:20 dilution, and cells were grown to the exponential phase (optical density at 660 nm [OD₆₆₀] of 2). For strain 8826(pMEC46), induction was performed by adding 20 ng of nisin (Sigma, St. Louis, Mo.) per ml 1 h after dilution and further incubation at 37°C for 5 h (24). The cells were then washed twice with sterile phosphate-buffered saline (PBS) and adjusted to 10¹¹ CFU per ml. For chemical inactivation of bacteria, suspensions of 5 × 10⁹ CFU per ml in MRS medium were treated with 200 µg of mitomycin C (MitC; Sigma) per ml for 90 mn at 37°C. The treated cells were washed twice in sterile PBS and resuspended at 10¹¹ CFU per ml for immunization. An aliquot of serial dilutions was plated on selective MRS agar in order to calculate the efficiency of the treatment.

Immunoblotting assay. Ten microliters (10⁹ CFU) of each inoculum was resuspended in 1 ml of 10 mM Tris (pH 8) buffer containing lysozyme (1 mg/ml; Sigma). After 30 min of incubation at 37°C, the cells were washed once in 10 mM Tris-HCl (pH 8) and lysed by addition of 100 µl of lysis buffer (10% glycerol, 2% Sodium dodecyl sulfate, 375 mM Tris-HCl [pH 7.6]). An aliquot (10 µl) of each cell extract was submitted to sodium dodecyl sulfate-polyacrylamide gel electrophoresis in a 10% gel as described by Laemmli (12). After transfer to nitrocellulose membranes by electroblotting, the specific proteins were detected with a rabbit anti-TTFC polyclonal serum (kindly provided by Innogenetics N.V., Ghent, Belgium) and revealed by alkaline phosphatase-conjugated goat anti-rabbit immunoglobulin G (IgG; Promega, Madison, Wis.).

Immunizations. Eight-week-old female C57BL/6 N Crl BR mice (Charles River Laboratories, St. Aubin-les-Elbeuf, France) were immunized intranasally. Initially, groups of eight mice were anesthetized by intraperitoneal injection of 200 µl of a 5% sodium pentobarbital solution (Sanofi, Libourne, France) or 150 µl of a cocktail (as described in reference 2) containing 20% Imalgene 1000 (Merial, Lyon, France), 0.5 mg of Valium (Roche, Neuilly-sur-Seine, France), and 62.5 µg of atropine (Aguettant Laboratory, Lyon, France) per ml. Ten microliters (10⁹ CFU) of the bacterial suspension was then instilled into one nostril of each mouse. Control groups received 10 µl of buffer alone (PBS) or 10 µg of purified recombinant TTFC (Boehringer Mannheim, Mannheim, Germany) mixed with 1 µg of cholera toxin B subunit (CTB) as the mucosal adjuvant (Sigma). Antigens were given at 3-week intervals by one (single dose) or two consecutive (double dose at 24-h interval) intranasal administrations. Ten days after each administration (priming and two boosts), serum samples were collected and stored at 20°C until use. Bronchoalveolar lavage fluids (BALF) were obtained 10 days after the final boost by three consecutive lavages of the lungs with a total volume of 400 µl of PBS containing complete protease inhibitor cocktail (Boehringer Mannheim). After 10 min of centrifugation at 4,000 × g (at 4°C), the supernatants were collected and stored at 20°C until analysis.

ELISA for detection of antigen-specific serum or mucosal antibody responses. Purified antigen (TTFC; Boehringer Mannheim) was coated overnight at 4°C on enzyme-linked immunosorbent assay (ELISA) plates (Immulon I; Dynatech, McLean, Va.) at 200 ng per 100 µl in 0.1 M carbonate-bicarbonate buffer (pH 9.5). After 1 h of saturation with PBS containing 3% bovine serum albumin (BSA; Sigma), samples were tested using twofold serial dilutions from a 1:50 dilution (for primary antisera) or a 1:2 dilution (for BALF) in PBS containing 1% BSA. After overnight incubation at 4°C, the plates were washed three times in PBS containing 0.1% Tween, and secondary anti-mouse biotinylated conjugate was applied in PBS containing 1% BSA and 0.1% Tween 20 at a 1:20,000 or 1:2,000 dilution for anti-mouse IgG (and IgG subtypes) or anti-mouse IgA (Southern Biotechnology Associates, Inc., Birmingham, Ala.), respectively. After 1 h of incubation at room temperature, horseradish peroxidase-conjugated streptavidine (Amersham, Buckinghamshire, United Kingdom) was applied at a 1:2,000 dilution in PBS containing 0.1% Tween for 30 min. After intensive washes (eight times), 1 mg of o-phenylenediamine substrate (Sigma) per ml in 0.2 M Na₂HPO₄-0.1 M citrate buffer (pH 5.5) containing 0.2% H₂O₂ was added and incubated for 30 min at 37°C. The reaction was stopped by addition of 50 µl of 2 N HCl, and the OD₄₉₀ was measured with an Elx800GUV automated microplate reader (Bio-Tek Instruments, Inc., Vinooski, Vt.). Endpoint titers were calculated as the reciprocal of the dilution producing the same OD₄₉₀ as 3 times the background, using the KC4 program (Kineticalc for Windows; Bio-Tek Instruments).

Statistical analysis. The results are expressed as the mean ± standard error of the mean (SEM). Statistical significance was evaluated by Mann-Whitney U test. Differences were considered significant at P < 0.05.

TTFC-specific T-cell response. Cervical lymph nodes (CLN) were aseptically removed (10 days after the last boost) and pooled for each group of animals; single-cell suspensions were prepared by mechanical dissociation using a homogenizer tube and passage through a nylon cell strainer (Becton Dickinson, Franklin Lakes, N.J.). After two washes, the cells were resuspended in complete medium RPMI 1640 (Gibco-BRL, Paisley, Scotland) containing 10% fetal calf serum (Boehringer Mannheim), 2 mM glutamine, 8 µg of gentamicin/ml, and 0.05 mM 2-mercaptoethanol. The cells were cultured at 37°C at a density of 2.5 × 10⁶ cells per ml, in the presence or absence of purified TTFC (different final concentrations) or heat-killed L. plantarum (10⁷ CFU/ml), for 4 days. To measure antigen-specific T-cell proliferative responses, [methyl-³H]thymidine (2.5 µCi/ml) was added to the culture 16 h before harvesting. The stimulation index (experimental/control) was determined in duplicate cultures.

Direct protection assay: TT challenge of mice. Immunized and control mice were challenged 13 days after the last boost (day 54) by subcutaneous inoculation of a standard challenge solution of TT. The number of 50% lethal doses (LD₅₀) administered in the experiment was concomitantly determined by injection of dilutions of the challenge solution in three groups of three age-matched naive mice and by calculation of the LD₅₀ by the method of Reed and Muench (27). The animals were observed each day. Mice showing no signs of paralysis 96 h after the challenge were considered fully protected; those surviving with signs were considered partially protected. Unprotected mice died at the latest on the second day after the challenge.

Indirect protection assay: determination of TT neutralizing antibodies in mouse sera. The toxin neutralization test was performed on the pooled sera of each group of immunized and control mice according to the specifications of the European Pharmacopoeia, with slight modifications. In brief, mixtures containing serial twofold dilutions of a pool and a definite amount of TT (L+/4,000 level) were injected subcutaneously in two OF1 mice (obtained from the animal facility, Institut Pasteur de Bruxelles) per mixture. A series of dilutions of a standard antitoxin solution mixed with the same toxin amount was included in each experiment. The neutralizing antibody content is expressed, in international units (IU) per milliliter, as a range that includes the actual value. Due to the small volumes of sera that were available, the detection limit was 0.0025 IU per ml of pooled sera. The protective level of tetanus antitoxin is usually considered to be 0.01 IU/ml (16).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

TTFC production by recombinant strains. To estimate the TTFC amount contained in the different inocula, cell extracts corresponding to 1/10 of each bacterial dose (10⁸ CFU) were analyzed by immunoblotting. As shown in Fig. 1, a specific signal at the expected molecular mass (47 kDa) was detected for both types of TTFC-producing strains. TTFC production was notably higher in strain 8826(pMEC46) (inducible p_nisA) than in 8826(pMEC4) (constitutive p_ldh). No specific signal was detected from the control strain cell extracts [8826(pTG2247)]. These results confirmed previous analysis (24; Chagnaud et al., unpublished) and were reproducible for each preparation.

View larger version (19K): [in this window] [in a new window]   FIG. 1.   Immunoblot analysis of recombinant L. plantarum cell extracts (equivalent to 108 CFU) of 8826(pTG2247) (control strain) (lane 1), 8826(pMEC4) (lane 2), 8826(pMEC46) (lane 3), and of 50 ng of purified TTFC (lane 4).

Role of anesthesia procedure. Two different anesthetic protocols were evaluated. When mice were anesthetized with pentobarbital, not only they were not completely relaxed and therefore sneezed (loss of material), but a large part of the inoculum was swallowed. This was checked (data not shown) by an instillation assay of bacteria mixed with trypan blue, followed by a postmortem examination which showed that most of the inoculum was located in the stomach (blue colored), with only a small portion reaching the lung (data not shown). Similar experiments performed with the anesthetic cocktail (2) showed that all of the inoculum reached the lungs and bronchi and that no liquid was swallowed (absence of blue color in the stomach). We verified that there were larger variations in the individual immune responses and less reproducible levels of anti-TTFC serum IgG with the pentobarbital treatment than with the anesthetic cocktail (results not shown). Therefore, the latter protocol was used in all subsequent immunization experiments.

Induction of serum IgG antibody responses. Two protocols differing in the number of bacterial doses received at each administration were compared in the same experiment. In the first, mice received a single dose of live recombinant L. plantarum strains; in the second, they were immunized on 2 consecutive days for each administration. In each case, two boosts were performed after the priming.

View larger version (36K): [in this window] [in a new window]   FIG. 2.   Anti-TTFC serum IgG titers following intranasal immunization with recombinant L. plantarum NCIMB8826. Individual sera were collected 10 days after the first () or second () boost from groups of eight mice intranasally immunized with buffer alone (PBS), with 109 CFU of control nonexpressing strain 8826(pTG2247), or with 109 CFU of TTFC-producing strain 8826(pMEC4) (constitutive promoter) or 8826(pMEC46) (inducible promoter) in a single dose (sd) or double dose (dd) at each administration. Bars represent the mean ELISA IgG titer ± SEM in each group.

View larger version (20K): [in this window] [in a new window]   FIG. 3.   Serum anti-TTFC antibody isotype titers after intranasal immunization with a single dose (109 CFU) of 8826(pTG2247) (), 8826(pMEC4) (), or 8826(pMEC46) () or a double dose (109 CFU twice at 24 h interval) of 8826(pMEC4) (). Isotypic responses were analyzed by ELISA on pooled sera of each group collected 10 days after the last boost.

Induction of local antibody and cellular responses. The mucosal IgA response in BALF was determined 10 days after the second boost. Nasal administration of the recombinant strains led to a significant (P < 0.05) anti-TTFC IgA response in BALF in comparison with the control strain [8826(pTG2247)] or buffer alone (Fig. 4). In the single-dose protocol, the level of the response was not significantly different (P > 0.05) between 8826(pMEC4) and 8826(pMEC46). Nevertheless, local IgA levels were significantly higher (P < 0.05) in mice that received a double dose of the 8826(pMEC4) strain.

View larger version (13K): [in this window] [in a new window]   FIG. 4.   Anti-TTFC IgA levels in BALF from groups of eight mice immunized intranasally with a single dose (sd) or double dose (dd) of nonexpressing recombinant L. plantarum 8826(pTG2247) or TTFC-producing L. plantarum 8826 (pMEC4) (constitutive promoter, low TTFC dose) or 8826(pMEC46) (inducible promoter, high TTFC dose) or with buffer alone (PBS) as a control. Individual BALF samples were collected 10 days after the last boost, and specific IgA response was normalized according to the level of total IgA and expressed in specific activity (SA). Bars represent the mean IgA level ± SEM in each group.

View larger version (27K): [in this window] [in a new window]   FIG. 5.   Antigen-specific T-cell proliferative responses in CLN of mice immunized intranasally with PBS or with a single dose (sd) or double dose (dd) of 8826(pTG2247), 8826(pMEC4), or 8826(pMEC46). T cells were isolated from CLN 10 days after the second boost, pooled by group of mice, and cultured for 4 days at a density of 5 × 106 cells/ml in the presence or absence of purified TTFC at 5(), 10(), or 50() µg/ml or in the presence of heat-killed L. plantarum (107 CFU/ml) ().

TT neutralization capacity of serum antibodies. Because mice were sacrificed for local and cellular response analysis, the protective effect of the circulating antibodies was assessed by an indirect method, i.e., the ability of elicited antibodies to neutralize TT and to protect naive mice against its lethal effect. As shown in Table 1, all recombinant strains elicited detectable neutralizing antitoxin antibodies, but only for L. plantarum 8826(pMEC46) was the level higher than the protective limit (>0.01 IU/ml) and obtained as early as the first boost. In this case, a neutralizing titer 10 times higher than the protective limit was measured after the second boost (0.08 to 0.16 IU/ml).

Responses elicited by live or MitC-treated recombinant L. plantarum strains. We further studied the effect of bacterial viability on the immune response after intranasal immunization. Both recombinant L. plantarum 8826(pMEC4) and 8826(pMEC46) were administered live (10⁹ CFU) or after inactivation with MitC treatment. More than fourfold loss of viability was obtained after MitC treatment, the administration of 10⁹ total cells thus corresponding only to 0.5 × 10⁵ viable cells (CFU). No difference in antigen level production was observed after inactivation, as analyzed by Western blotting analysis (data not shown). As shown in Fig. 6, chemically inactivated recombinant L. plantarum elicited systemic IgG response, as measured by ELISA, in the same magnitude as that induced with live vectors. The difference between the response elicited by inactivated and live 8826(pMEC4) was not significant (P > 0.05) except after the second boost, when the live vector was 10 times more immunogenic. For 8826(pMEC46), no significant differences were found between live and inactivated strains (P > 0.05). The levels of IgG antibody response were very similar to those obtained in the previous experiments with both vectors. Strain 8826(pMEC46) induced a higher systemic IgG response (P < 0.05) than strain 8826(pMEC4), (43,6014 ± 33,928 and 61,595 ± 48,162, respectively) after the second boost. The level of the response induced by strain 8826(pMEC46) was not significantly (P > 0.05) different from that elicited by intranasal administration of 10 µg of purified TTFC in the presence of 1 µg of (CTB) as the mucosal adjuvant (Fig. 6).

View larger version (18K): [in this window] [in a new window]   FIG. 6.   Anti-TTFC serum IgG titers following intranasal immunization with recombinant L. plantarum NCIMB8826. Individual sera were collected 10 days after the priming and the first and second boosts from eight mice immunized intranasally with PBS () with 109 CFU of live 8826 (pTG2247) (), live () or MitC-treated () 8826(pMEC4) or live () or MitC-treated (----) 8826(pMEC46), or with 10 µg of purified TTFC in the presence of 1 µg of CTB (×). Bars represent the mean ELISA IgG level ± SEM in each group.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The main goal of this investigation was to ascertain whether mucosal immunization with recombinant lactobacilli would stimulate systemic and local antibody responses and exhibit a protective ability. To this end, intranasal administration was explored using as a model antigen the 47-kDa TTFC produced intracellularly by recombinant L. plantarum NCIMB8826 strains. Two main parameters were examined: effect of antigen dose, and viability of the vaccine vector. Prior to conducting these studies, we adjusted the anesthetic protocol to ensure minimal individual variation and high reproducibility of the immune responses induced after intranasal immunization. The procedure described in this report fulfilled these needs better than the pentobarbital treatment.

In this study, we compare the immunogenicity of isogenic antigen-producing strains where the heterologous gene was cloned under the control of one of two different promoters (constitutive or inducible), leading to doses of antigen that were estimated to vary from 1 to 10% of the intracellular protein content. Even if after one boost the strain producing a high amount of TTFC (single-dose protocol) was more immunogenic than the strain synthesizing less antigen (single or double-dose protocol), the levels of circulating IgG after the second boost were very high and quite similar for both constructions when measured by ELISA. The endpoint titers reached levels above 10⁵. The protective response against TT correlated to the level of antigen production, indicating that immunization with higher amounts of antigen could have induced IgG with higher avidity. Indeed, induction of a sufficient amount (>0.01 IU/ml) of antibodies to neutralize TT in vivo, i.e., high-avidity circulating IgG directed against protective epitopes, is a prerequisite for protection against tetanus. The neutralization test used in this work measures such antibodies. On the contrary, sandwich ELISA takes into account antibodies directed against both protective and nonprotective epitopes, whatever their avidity. The discrepancy between the results obtained with these methods is well established, especially at low neutralizing antibody concentrations and in the early phases of primary immunization. This problem can generally be overcome by using competition or inhibition variants of the ELISA (6, 32). However, sandwich ELISA remains widely used in studies using TTFC as a model antigen for evaluation of new vaccine strategies, as it is rapid and easy to perform, relies on readily available reagents, and, interestingly, needs very low serum volumes. Our results emphasize once more that protection cannot be deduced solely from titers of circulating anti-TTFC IgG, as determined by sandwich ELISA, and that it is necessary to apply methods able to reflect the neutralizing potency of elicited antibodies when evaluating the potential of the delivery system under study. In the case of tetanus, these methods include in vivo challenge with TT, in vivo neutralization test, or in vitro assays using appropriate standards and validation by comparison with neutralization test results.

Different mucosal presentations of antigen have been recently designed for protection against TT, including oral or intranasal administrations of TTFC with cholera toxin (5, 9) or recombinant live vectors expressing TTFC, e.g., Salmonella (1, 3, 34). Recent work on protection against TT with DNA-based vaccines (30) has shown that they induce preferentially cytotoxic T-cell responses dominated by a T helper type 1 propensity and a lower antibody response and then are less efficient than a polypeptide subunit vaccine which induces a protective Th2 response. Mucosal administration (intranasal or oral) able to initiate a protective antibody response should thus be advantageous for vaccination against tetanus with respect to safety, low cost, and ease of administration (4).

In the case of lactobacilli, the isotypic response obtained after intranasal administration of recombinant strains showed a high IgG2b and IgG1 response associated with a moderate level of IgG2a response. This suggests that recombinant Lactobacillus strains are able to activate both Th1 and Th2 T helper cell subsets. Similar results have been obtained after intranasal and intragastric immunization of mice with recombinant L. lactis producing TTFC, which also conferred a protective immune response (22, 28). In the case of L. plantarum, immune responses against the vector itself were not detectable (i.e., absence of proliferative responses in cervical lymph nodes after in vitro restimulation with heat-inactivated bacteria), while for L. lactis low serum antibody responses directed against the bacteria were detected (28). This contrasts with the Th1 (IgG2a isotype) profile elicited by oral administration of recombinant Salmonella as well as the higher innate antigenicity of other recombinant bacterial vectors, e.g., Mycobacterium bovis BCG, Bordetella, and Salmonella (3, 10, 19). The nature of the immune response elicited by a given bacterial vector with respect to Th1 versus Th2 and humoral versus cellular immunity can differ considerably and should thus be taken into account during selection of the bacterial vector to be used.

Shaw et al, (31) recently described successful mucosal immunization with recombinant lactobacilli expressing TTFC intracellularly or at the cell surface, which were able to induce systemic IgG responses reaching endpoint titers of 10⁴ or 10² after intranasal or intragastric administration, respectively, to mice. However, protection was not evaluated in this study. Local IgA responses were detectable after priming and boosting with three successive bacterial doses (days 1 to 3). With the system we describe, significant local IgA responses were measured in BALF, and antigen-specific T-cell proliferative responses were elicited by both types of recombinant lactobacilli [8826(pMEC4) and 8826(pMEC46)]. The levels were higher when mice received two consecutive doses at each administration, but responses were readily detectable after a single dose. Our results support the hypothesis (31) that the absolute levels of TTFC produced by the lactobacilli is probably a key factor in their immunogenicity, as illustrated by the IgG titers induced by the isogenic pair of L. plantarum strains producing low [8826(pMEC4)] or high [8826(pMEC46)] amounts of the same antigen.

In addition, we evaluated the impact of the viability of the bacterial vector on the induction of protective immune responses. Comparable serum IgG responses (as measured by ELISA) were obtained with live and inactivated recombinant lactobacilli, as also observed for TTFC-producing L. lactis strains administered by the nasal route (28). In the latter case, this effect was not unexpected, as this nonpersisting bacterium might be considered a live antigen-loaded particle. However, no comparison of protection was conducted with live and dead L. lactis (28). In our case the level of protective response was 10-fold higher with the live 8826(pMEC46) strain. Possibly different cytokine induction patterns were initiated by live and MitC-treated recombinant bacteria. It was recently reported that in vitro adhesion of probiotic strains to intestinal cell lines was affected differently depending on the bacterial killing or inactivation procedure (23). If applicable to the in vivo situation, this observation may, at least partly, explain why live and dead lactobacilli differ in their immunogenicity or immunomodulation capacity. Nevertheless, no differences in isotypic response were observed after administration of live and inactivated Lactobacillus vectors.

In conclusion, the results obtained so far (reference 31 and this study) demonstrate that lactobacilli are capable of delivering antigen to the mucosal and systemic immune systems following intranasal immunization. The development of lactic acid bacteria as vaccine delivery vehicles involves the use of various strains which are able to colonize different mucosal sites such as the gastrointestinal, urinary, and genital tracts and could thus be used specifically to vaccinate against pathogens at their site of entry. While both gut colonizers and noncolonizers seem to work equally well by the systemic and nasal routes, the importance of colonization or adhesion in oral administration remains an open question. We therefore plan to examine the potency of our recombinant L. plantarum strains as oral vaccines, with a special focus on the effect of persistence time in the gastrointestinal tract.