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Infect Immun, August 1998, p. 3862-3866, Vol. 66, No. 8
Instituto de Investigaciones Biotecnologicas,
Received 12 January 1998/Returned for modification 18 February
1998/Accepted 22 April 1998
A vector for the expression of foreign antigens in the vaccine
strain Brucella abortus S19 was developed by using a DNA
fragment containing the regulatory sequences and the signal peptide of the Brucella bcsp31 gene. This fragment was cloned in
broad-host-range plasmid pBBR4MCS, resulting in plasmid pBEV. As a
reporter protein, a repetitive antigen of Trypanosoma cruzi
was used. The recombinant fusion protein is stably expressed and
secreted into the Brucella periplasmic space, inducing a
good antibody response against the T. cruzi antigen. The
expression of the repetitive antigen in Brucella neither
altered its growth pattern nor generated a toxic or lethal effect
during experimental infection. The application of this strategy for the
generation of live recombinant vaccines and the tagging of B. abortus S19 vaccine is discussed. This is the first time that a
recombinant protein has been expressed in the periplasm of brucellae.
Brucellosis remains a major zoonosis
in several countries (3). In cattle, brucellosis is the
consequence of infection with the facultative intracellular pathogen
Brucella abortus, which causes abortion and infertility in
cattle and a clinical manifestation known as undulant fever in humans
(15). To control the infection, especially in countries with
large cattle populations, vaccination with attenuated strain B. abortus S19 is a widely accepted approach (16). The
outstanding characteristics of this strain are its low pathogenicity
and the high level of protection conferred. S19 has an
as-yet-uncharacterized alteration but is effective at preventing
abortions caused by infections with field strains of B. abortus (16). However, the antigenic similarity between S19 and virulent field strains, mainly in the immunodominant
lipopolysaccharide antigen, hampers discrimination between infected and
vaccinated animals. This is due to the occurrence and persistence of
serum antibodies following strain S19 vaccination, which interferes with the detection of infected animals (2, 23). Alternative ways to work out these problems by using a specific monoclonal antibody
or by using a deletion mutant as a vaccine strain have been described
(17, 20). Other untested alternatives are the expression of
a foreign protein in B. abortus S19. This would result in a
tagged vaccine with a distinctive immunological signature, allowing
easy differentiation between vaccinated and infected animals.
B. abortus is a well-known Th1 response inducer (5,
21) and, in addition, has been used as a carrier to induce a
T-cell-independent immune response against molecules conjugated with
the bacterium (7, 24). Thus, the strong humoral and cellular
responses it generates in the host make B. abortus S19 an
attractive alternative as a live carrier of heterologous antigens. For
tagging of the available S19 vaccine and its possible use as a live
vaccine carrier, it is necessary to express foreign proteins in
Brucella without affecting its immunological properties. In
this report, we describe the development of an expression vector for
Brucella using the promoter and secretion signals from
bcsp31, a gene encoding an immunodominant
Brucella protein (14). The application of this strategy in the generation of a tagged B. abortus S19
vaccine is discussed.
Bacterial strains and growth conditions.
Attenuated vaccine
strain B. abortus S19 was obtained from the Comisión
Nacional de Energía Atómica, División Agropecuaria, Buenos Aires, Argentina. For mating experiments, B. abortus
S19 was grown at 37°C on a rotary shaker (200 rpm) for 24 to 48 h in tryptic soy broth containing 5 µg of nalidixic acid per ml. For
all other experiments, B. abortus S19 or the recombinant
strain carrying plasmid pBEV was grown at 37°C for 48 h in
tryptic soy agar (TSA) or in TSA containing 50 µg of carbenicillin
per ml in the case of the recombinant strain. Escherichia
coli DH5 Construction of an expression vector for Brucella.
A
250-bp DNA fragment encoding the putative promoter region, the start
codon, and the first 31 codons, corresponding to the signal peptide, of
the bcsp31 gene of B. abortus S19, described by
Mayfield et al. (14), was amplified by PCR using the upper primer 5'-gACTggATCCgCggCCgCCTgCAA-3' and the
lower primer 5'-ACTggTACCCggggCCTgTgCAAC-3'. These primers contain BamHI and KpnI sites
(underlined), respectively, to facilitate the cloning procedures. As
template DNA, a pUC19-derived vector containing the entire
bcsp31 gene previously constructed in our laboratory was
used. The 250-bp fragment was inserted into the
BamHI-KpnI sites of the pUC19 plasmid polylinker.
The resulting DNA construct was introduced into the competent strain
E. coli DH5 Experimental infection of mice.
Nine-week-old female BALB/c
mice were injected intraperitoneally with approximately 2 × 107 CFU of brucellae in 0.2 ml of NaCl (150 mM). Groups of
eight mice were injected either with B. abortus S19 or with
the recombinant strain B. abortus S19(pBEV-REP).
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Vector Development for the Expression of Foreign
Proteins in the Vaccine Strain Brucella abortus
S19
ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
(F'Iq) was used for the
construction of plasmid pBEV and in all cloning experiments. E. coli S17.1 (Nals) was used as the donor strain in
biparental mating procedures.
(F'Iq) as described by
Inoue et al. (9), and the construction was analyzed by
restriction analysis and DNA sequencing. The recombinant plasmid
containing the promoter region, the start codon, and the signal peptide
encoding the Brucella bcsp31 gene, together with a linker
sequence to facilitate the construction of a recombinant DNA expressing
a fusion protein under the control of the Brucella promoter,
was designated pUC-PROM.
(F'Iq), and the expression of the new
recombinant fusion protein was analyzed by DNA sequencing and Western
blotting. E. coli S17.1 carrying pBEV or pBEV-REP was used
as the donor for conjugative transfer of this plasmid to B. abortus S19.
View larger version (15K):
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FIG. 1.
Diagrammatic representation of plasmid pBEV-REP. The
thin line represents pBBR4MCS sequences. The unshaded box represents
the cloned B. abortus S19 fragment containing the promoter
(Prom), regulatory sequences, and signal peptide (SP) of the
bcsp31 gene. The nucleotide and peptide sequences of the
first 31 amino acids and the linker sequences are indicated. The shaded
box represents the repetitive T. cruzi reporter protein. The
consensus sequence of the repeat is indicated.
20°C
until used. Spleens were removed, weighed, and cut into thirds. The
tissue used for bacterial counting was weighed and homogenized in 1 ml
of NaCl (150 mM). Tissue homogenates were serially diluted and plated
in duplicate on TSA or on TSA containing 50-µg/ml carbenicillin in
the case of the recombinant strain. Colonies were counted after 4 days
of incubation at 37°C.
Western blotting. Sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE) was performed as described by Laemmli (12). Periplasmic extracts were obtained by the Zwittergent-lysozyme extraction method developed by Stabel et al. (22). Periplasmic fraction, protoplastic fraction, and whole-cell lysates were solubilized in Laemmli buffer at 100°C, electrophoresed by SDS-10% PAGE, and transferred to nitrocellulose filters. The filters were reacted with hyperimmune rabbit antirepeat serum diluted 1:500 (18), incubated with peroxidase-conjugated goat anti-rabbit immunoglobulin (Dako Immunoglobulins) diluted 1:1,000, and stained with 4-chloro-1-naphthol (used as a chromogen; Sigma Chemical Co., St. Louis, Mo.). To study the immune response against the recombinant protein expressed by Brucella, 50 ng of glutathione S-transferase-T. cruzi repeats (GST-REPEATS) purified protein from E. coli (18) was solubilized in Laemmli buffer, electrophoresed by SDS-10% PAGE, transferred to a nitrocellulose filter, and reacted with sera from infected mice. The filters were incubated with 125I-labeled protein A (Dupont NEN Research Products, Boston, Mass.).
KELA. Antibodies against B. abortus lipopolysaccharide (LPS) and the T. cruzi repetitive antigen were measured in an indirect, computer-assisted kinetics-based enzyme-linked assay KELA, as described by Winter et al. (25). The indirect ELISA to measure antibodies against Brucella LPS in mice sera was performed as described by Nielsen et al. (17), with some modifications. The indirect ELISA to detect antibodies against the T. cruzi repetitive antigen was performed as described by Buscaglia et al. (3). For both assays, mice sera were diluted 1:25 and horseradish peroxidase-conjugated goat anti-mouse immunoglobulin (Jackson ImmunoResearch Laboratories, Inc., West Grove, Pa.) was diluted 1:2500. The rate, expressed as the slope, was directly proportional to the amount of antibody in the sample and was determined from linear regression analysis of time versus absorbance (25). The slope values (103) were plotted for each serum sample.| |
RESULTS |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Construction of an expression vector for B. abortus and expression of a reporter protein. The development of an expression vector for Brucella requires that the gene to be expressed be under the control of a constitutive promoter, due to the impossibility of using an inducer in the infected animal. We chose the bcsp31 promoter because the BCSP31 protein is expressed during the complete life cycle of the bacteria. Moreover, antibodies to the BCSP31 protein are detectable by using sera of vaccinated and infected animals (1, 8). The fact that this promoter is also functional in E. coli facilitates the construction of the expression vector (14). A 250-bp fragment containing the putative promoter, regulatory sequences, and the region of bcsp31, encoding the first 31 amino acids, which includes the signal peptide, was cloned into broad-host-range plasmid pBBR4MCS, a plasmid that is replicative in Brucella (10, 11). Downstream of the codon for Pro-31, a linker sequence containing KpnI, SacI, and EcoRI sites was added to allow in-frame fusions. We named this vector pBEV (see Materials and Methods). As a reporter protein, we used a molecular tag made up of a repetitive antigen from the protozoan parasite T. cruzi (19). A scheme of the resulting construct is shown in Fig. 1. The corresponding reporter gene, consisting of the 5' and 3' nonrepeat coding regions with a core of 14 tandemly arranged 36-base-long repeats, was inserted into the correct reading frame in the EcoRI site of the linker. This plasmid was named pBEV-REP.
B. abortus S19 was transformed by biparental conjugation with either plasmid pBEV (control) or pBEV-REP. The expression of the reporter protein was analyzed in whole-cell extracts and periplasmic and protoplastic fractions by Western blotting using specific rabbit antiserum raised against the reporter antigen. As seen in Fig. 2, two strongly reactive bands with apparent molecular masses of 55 and 45 kDa were visible in whole-cell extracts of bacteria transformed with pBEV-REP (Fig. 2, lane 3). Bands likely to have resulted from degradation of the repetitive units were also observed (18, 19). The recombinant product was translocated to the periplasmic space (Fig. 2, lane 1) and was almost undetectable in the protoplastic fraction (Fig. 2, lane 2). The recombinant protein was also expressed in the donor E. coli strain carrying pBEV-REP (Fig. 2, lane 5). This was not unexpected, since the BCSP31 promoter had previously been reported to be active in E. coli (14). The serum failed to react with whole-cell extracts from B. abortus S19 that had been transformed with pBEV, which lacks the DNA insert encoding the reporter protein (Fig. 2, lane 4).
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The reporter protein expressed in B. abortus S19 is immunogenic in the course of an experimental infection. The next question was whether the reporter protein expressed by the transformed B. abortus is able to generate an immune response in the course of an experimental infection in the mouse model. B. abortus S19 and B. abortus S19(pBEV-REP) were used to infect BALB/c mice (see Materials and Methods), and at different days postinfection, sera were collected and analyzed for the presence of specific antibodies against a recombinant GST-REPEATS fusion protein by Western blotting (18) (Fig. 3). Antibodies against the reporter protein in sera from animals infected with B. abortus S19(pBEV-REP) were detectable after 18 days of infection (Fig. 3B). Antibodies against the reporter protein were not detectable in sera from animals infected with B. abortus S19 (Fig. 3A).
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B. abortus S19 and the recombinant bacteria generate similar infections in mice. Basic parameters of Brucella infection were analyzed to find out if there was any gross modification of the infection process due to expression of the foreign protein. Mice were infected with either parental B. abortus S19 or B. abortus S19(pBEV-REP); animals were sacrificed at different times after infection, and the spleen weights and the numbers of CFU recovered from the spleens were analyzed (Table 1). Mice infected with S19 (six animals) and S19(pBEV-REP) (eight animals) controlled the infection and survived. Significant splenomegaly, a characteristic consequence of Brucella infection, was observed in both groups of animals starting at about days 18 to 20 of infection (Table 1). The numbers of CFU recovered from the spleen were similar for S19(pBEV) and S19(pBEV-REP). The numbers of CFU clearly decreased to similar levels at day 30 after infection, indicating that B. abortus growth was controlled in both cases.
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DISCUSSION |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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In designing an expression vector for B. abortus, we took into consideration some aspects for the selection of the gene to be used. First, the gene promoter selected should constitutively express the recombinant product at levels compatible with the generation of a specific immune response. Second, the sequences selected should encode a signal peptide in order to secrete the recombinant product into the periplasm of the bacteria. This should prevent toxicity and the generation of inclusion bodies frequently found when a recombinant protein is expressed constitutively or at high levels by a strong promoter. We chose the regulatory sequences and the secretory signal of the gene encoding BCSP31, a periplasmic B. abortus protein which is highly antigenic during natural infections and after vaccination (1, 14). In this work, we showed that a recombinant protein can be stably expressed in Brucella with the designed vector. Most of the recombinant protein was detected in the periplasmic space of the bacteria, presumably in a soluble form because that it remained in the supernatant after the mild treatment used to extract the periplasmic content.
The recombinant bacteria generate a strong antibody response in mice against the heterologous protein. This result indicates that the expression vector is stably maintained without selective pressure and that the promoter sequence selected actively expresses the reporter protein during the infection process.
The expression of the repetitive antigen in Brucella does not alter its growth pattern, and in a preliminary study, it failed to generate a toxic or lethal effect in the BALB/c mouse model.
Previous studies have shown that pBBR4MCS replicates in all Brucella species (6). Therefore, the strategy we describe here can be extended to the other live Brucella vaccines, including B. melitensis Rev1, B. suis S2 and B. abortus RB51.
Although in this work we have expressed a reporter protein to demonstrate the feasibility of the approach, it might be possible to express in this vector epitopes protective against other cattle pathogens. The advantage of using a live, attenuated bacterial carrier like B. abortus S19 is the strong immune response it generates after immunization. In the model that we tested in this work, an autonomous replicating vector with an antibiotic resistance marker was used. In developing a live vaccine carrier, however, it might be convenient to generate a vector that integrates itself into the bacterial genome to prevent it from being lost after successive divisions in the absence of any antibiotic selective pressure.
Another possible application of the approach described is tagging of the Brucella vaccine. A major problem in many countries in which vaccination against Brucella is mandatory is the difficulty in differentiating between vaccinated and infected animals (13). The antibody response is, in both cases, directed to similar antigens, particularly if a complex antigenic bacterial extract is used as the reagent for antibody detection. The use of a vaccine having a distinctive immunological signature as an antigenic tag might allow quick identification of immunized animals through a simple ELISA using either synthetic peptides or a recombinant protein. Different synthetic repeats could be included on Brucella in different vaccination campaigns or to label products from different companies.
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ACKNOWLEDGMENTS |
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We thank Michael Kovach for providing pBBR4MCS, Juan Jose Cazzulo for his helpful comments, and Fabio Fraga for technical assistance.
This work was supported by grants from the Comision Nacional de Energia Atomica and the Universidad Nacional de General San Martin. The research of A.C.C.F. was supported in part by an International Research Scholars Grant from the Howard Hughes Medical Research Institute and the International Atomic Energy Agency, Vienna, Austria.
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FOOTNOTES |
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* Corresponding author. Mailing address: Instituto de Investigaciones Biotecnologicas, Universidad Nacional de General San Martin, INTI, Av. General Paz y Albarellos (Ed. 24), Casilla de Correo 30 (1650), San Martin, Provincia de Buenos Aires, Argentina. Phone: (54-1) 752-0021. Fax: (54-1) 752-9639. E-mail: rugalde{at}inti.gov.ar.
Editor: J. R. McGhee
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Infect Immun, August 1998, p. 3862-3866, Vol. 66, No. 8
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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