Background
Coxiella burnetii is an obligate intracellular bacterium that causes the zoonotic disease Q fever. Acute Q fever typically manifests as an incapacitating, flu-like illness with symptoms including high-grade fever and periorbital headache [
1].
C. burnetii can persist in its host in a latent state and may reactivate to cause chronic Q fever months or years after initial exposure [
2]. Historically, several different Q fever vaccines have been developed, the most successful of which has been an Australian vaccine, Q-vax, that consists of formalin inactivated
C. burnetii [
3]. One dose of Q-vax provides long-lived protective immunity [
4]. However, this vaccine can cause severe side effects in recipients with previous exposure to
C. burnetii necessitating skin testing to determine the immune status of potential vaccinees prior to vaccination. Thus, there is a clear need for a safe, effective subunit vaccine that eliminates the need for pre-testing.
Despite the effectiveness of Q-vax, little is known about the immune mechanisms responsible for the protective immunity elicited by this vaccine. Due to the intracellular niche of
C. burnetii, it has long been thought that cell-mediated immunity (CMI) must be required for protection against this pathogen. In support of this idea, Andoh
et al. [
5] recently found T cells and interferon-γ are essential for resolution of a primary
C. burnetii infection. While CMI plays an important role in immunity to
C. burnetii, passive immunization studies, where serum from vaccinated animals is transferred into naïve animals, clearly demonstrate that Ab alone is capable of providing complete protection in an immunocompetent animal [
6‐
10]. The development of potential subunit vaccine candidates would benefit from a deeper understanding of the precise mechanisms responsible for AMI to
C. burnetii.
Antibody can provide protection against intracellular pathogens via a number of different mechanisms. These include direct bactericidal activity, complement activation, opsonization, cellular activation via Fc or complement receptors, and Ab-dependent cellular cytotoxicity [
11]. Here, we have examined the potential contributions of FcR and complement in AMI to
C. burnetii.
Discussion
Despite the obligate intracellular niche of C. burnetii, passive transfer of Ab to a naïve, immunocompetent animal provides complete protection against challenge with this pathogen. We sought to determine the specific immune mechanisms responsible for Ab-mediated protection against C. burnetii. The fact that Ab alone can protect against C. burnetii challenge is even more intriguing because this organism replicates within a phagolysosome-like compartment of mononuclear phagocytes. Therefore, the opsonic mechanisms that are traditionally thought to target infectious organisms to phagocytes where they are destroyed in phagolysosomes are not likely to play a role in AMI to C. burnetii. In support of this, we show here that Ab opsonization does not directly affect bacterial viability or intracellular replication of C. burnetii in human MΦ. Additionally, our passive immunization experiments with FcR k/o mice indicate that traditional opsonic mechanisms, which are typically FcR-dependent, are not essential for AMI to C. burnetii.
There are conflicting reports of the ability of Ab opsonized
C. burnetii to survive in phagocytes. Hinrichs and Jerrells [
15] found that immune serum opsonization of
C. burnetii increased bacterial uptake by guinea pig macrophages, but had no negative effect on the intracellular replication of the organism. Likewise, Kazar et al. [
16] and Baca et al. [
14] found that macrophages were unable to control the growth of Ab-opsonsized
C. burnetii. However, a study published by another group showed that immune serum opsonization allowed for increased uptake and destruction of
C. burnetii by guinea pig MΦ [
23]. Our data show that human monocyte-derived macrophages do not control growth of Ab-opsonized
C. burnetii in vitro. In interpreting these disparate results, it is important to keep in mind that these are in vitro studies that may not accurately reflect what is occurring in vivo. Further studies involving histological analysis of the fate of Ab-opsonized bacteria in vivo are clearly needed.
There have been several reports of protection of naïve animals from
C. burnetii challenge by passive immunization with immune serum. Interestingly, T cell deficient mice are not protected by passive Ab transfer [
9,
10]. Thus, whatever the mechanisms of AMI to
C. burnetii may be, they are dependent of the presence of T cells. DC express FcR, are stimulated by immune complexes, and are potent stimulators of naïve T cells. Therefore, we examined the response of DC to Ab-opsonized
C. burnetii and found that DC are stimulated by Ab-opsonized
C. burnetii in FcR-dependent manner. This led us to examine the role of FcR in AMI to
C. burnetii in vivo. Given the results of our in vitro experiments, we were surprised to find that AMI to
C. burnetii was totally independent of activating FcR. Thus, the FcR-dependent stimulation of DC, or any other cell type, by Ab-opsonized bacteria is not essential for protection.
The common γ-chain FcR k/o mouse used in our studies lacks expression of functional activating FcR. However, these mice still express the inhibiting FcRIIb that can bind immune complexes. It would be counterintuitive to expect an inhibiting FcR to contribute to protective immunity to a bacterial pathogen. However, there is one study showing that both activating and inhibiting FcR need to be knocked out in order to observe a defect in AMI to
Bordetella bronchiseptica [
24]. Thus,
C. burnetii may be similar in that both types of FcR need to be knocked out to see a defect in AMI. Interestingly, AMI to
B. bronchiseptica is also dependent on a functional complement system [
25], which is not true for
C. burnetii. Therefore, the mechanisms involved in AMI to
C. burnetii appear more complex than what is known about AMI to other pathogens.
There are several possible mechanisms by which FcR-deficient mice could be protected by passive administration of Ab. Immune sera against bacterial pathogens like
Neisseria meningitidis and
Borrelia burgdorferi are bactericidal towards the organism [
26,
27]. For
B. burgdorferi, Ab in immune serum can be directly bactericidal whereas, in the case of
N. meningitidis, the bactericidal activity of immune serum is dependent on a combination of Ab and complement. Our own data and those reported previously [
14‐
16] show that
Coxiella-specific antibodies from immune individuals or animals are not directly bactericidal. Indeed, Ab enhances uptake of the bacteria by cells and therefore promotes bacterial replication in vitro. Therefore, Ab opsonization does not affect the replication of
C. burnetii. Furthermore, the combination of anti-
Coxiella Ab and complement does not affect bacterial viability and the complement cascade is not essential for Ab-mediated protection in vivo.
There are several mechanisms by which complement can contribute to AMI. The C1q component of the classical complement pathway can recognize and bind to the Fc portion of Ab leading to activation of the classical complement cascade and deposition of complement on the surface of immune complexes. Mannose-binding lectin, a component of the lectin pathway of complement activation, can also bind to the Fc portion of IgM [
28]. The data presented here demonstrate that none of the pathways of complement activation play essential roles in AMI to
C. burnetii.
It is possible that in the absence of activating FcR, the complement system can compensate and allow for passive protection of FcR-deficient animals and vice versa. Thus, it would be interesting to examine passive immunity in animals deficient in both FcR and complement.
Methods
C. burnetii Purification and Antiserum Production
C. burnetii Nine Mile phase I (RSA493) was propagated in African green monkey kidney (Vero) fibroblasts and purified by Renografin density gradient centrifugation [
18]. Purified bacteria were suspended in K-36 buffer (0.1 M KCl, 0.015 M NaCl, 0.05 M K
2HPO
4, 0.05 M KH
2PO
4, pH 7.0). Murine anti-
Coxiella antiserum was prepared by immunizing C57Bl/6 mice i.p. three times at 2 wk intervals with 10
8 fixed
C. burnetii. C. burnetii were fixed with 4% paraformaldehyde for 24 h at 4°C. The bacteria were washed three times with phosphate buffered saline (PBS, Invitrogen, Carlsbad, CA) and resuspended in PBS at the desired concentration. Immune sera were harvested 2 wks after the final immunization and pooled. Serum from unvaccinated mice was harvested as naïve (control) serum. Human serum from a chronic Q fever patient was generously provided by Ted Hackstadt, Rocky Mountain Laboratories, NIAID, NIH.
Cell Culture
Human monocyte-derived DC were prepared as previously described [
19]. Briefly, human PBMC were isolated from buffy coats by centrifugation through a Ficoll-Paque Plus (Amersham Pharmacia Biotech, Uppsala, Sweden) density gradient. Cells were enriched for monocytes (CD14+ cells) using a RossetteSep Monocyte Enrichment Kit (Stem Cell Technologies, Vancouver, Canada). Monocytes were resuspended at 10
6 cells per ml in DC medium (RPMI +Glutamax [Invitrogen], 5% FBS, 15 mM Hepes, 0.1 mM non-essential amino acids, 1 mM sodium pyruvate, 100 U/ml penicillin and 100 μg/ml streptomycin) containing IL-4 (10 ng/ml) and GM-CSF (10 ng/ml) (Peprotech, Rocky Hill, NJ) and cultured for 6 days with replacement of half of the medium and addition of fresh cytokines every other day. Non-adherent DC were harvested by centrifugation and suspended in DC medium without antibiotics. The resulting cells were determined to be >95% CD11c+/CD209+ by flow cytometry. Monocyte-derived macrophages were generated by culturing monocytes in MΦ medium (RPMI, 10% FBS, and 50 ng/ml M-CSF [Peprotech]) for 7 days. Adherent MΦ were harvested by washing with cold PBS and gentle scraping.
The method used to prepare bone marrow derived DC (BMDC) was adapted from methods described by Inaba
et al. [
29]. Briefly, bone marrow cells were isolated from C57Bl/6 or FcR k/o mouse femurs and cultured in DC medium containing 20 ng/ml murine GM-CSF (Peprotech) at 37°C, 5% CO
2. After 3 days, the culture medium and non-adherent cells were removed and replaced with fresh DC medium containing fresh GM-CSF. The cells were cultured with replacement of half of the medium and addition of fresh cytokines every third day. After 6–8 days of culture, BMDC were harvested as non-adherent cells. These cells were determined to be >80% CD11c+/CD11b+ by flow cytometry.
For C. burnetii infection experiments, DC were plated in 24-well plates at a concentration of 5 × 105 per ml in DC medium. Purified C. burnetii were added directly to the culture medium at a multiplicity of infection (MOI) of 100. Unless otherwise indicated, the inoculum was not removed. LPS from E. coli serotype O111:B4 (Sigma, St. Louis, MO) was used at 500 ng/ml as a positive control for DC stimulation/maturation. Cells were mock-infected with K-36 buffer. For in vitro experiments in which C. burnetii were Ab opsonized, approximately 20 μl of a C. burnetii suspension (approximately 108 bacteria) were mixed with 50 μl of naïve or immune serum (human or mouse) and incubated for 30 min at room temperature. Bacteria were washed twice with PBS (Invitrogen) and resuspended at the desired concentration in PBS.
Mouse Strains
C57Bl/6 and Fc receptor common gamma chain k/o (Fcer1g) [
30] mice on a C57Bl/6 background were obtained from Taconic Farms (Germantown, NY). Breeding colonies of C2/factorB double k/o [
31] mice were maintained at Taconic Farms. MBL/C1q double k/o, MBL/factorD double k/o and C1q/factorD double k/o mice were generated by interbreeding MBL k/o [
32], C1q k/o [
33], and factorD k/o [
34] mice and maintained at Taconic Farms. All complement knockout mice were on the C57Bl/6 background (backcrossed at least 10 generations).
Passive Immunization Experiments
On day -1, mice were injected with 300 μl naïve or immune serum via the intraperitoneal (i.p.) route. On day 0, mice were challenged i.p. with 105 C. burnetii. Mice were sacrificed on day 14, spleens were harvested and blood was collected. Severity of infection was determined by measuring spleen weight and bacterial genomes per spleen. All procedures and animal protocols used in this study were approved by the Biosafety and IACUC committees at Rocky Mountain Laboratories. Work with viable C. burnetii was conducted in either BSL-3 or ABSL-3 laboratories.
Quantitative PCR
C. burnetii replication during infection of MΦ was quantified using TaqMan quantitative PCR (QPCR) of genome equivalents as previously described [
35]. Briefly, MΦ were incubated with
C. burnetii (MOI = 100) for 24 h at 37°C, 5% CO
2. Non-adherent bacteria were removed by washing MΦ with Hank's balanced salt solution and the medium replaced. This point was considered 0 h post-infection. MΦ were harvested by scraping and DNA was isolated with an UltraClean microbial DNA isolation kit (MoBio Laboratories, Carlsbad, CA). For determination of bacterial genome numbers in the spleen, a small portion of spleen tissue (<50 mg) was excised from the spleen, weighed, and DNA extracted using the same DNA isolation kit. The primers/probe set used was designed with PrimerExpress software (Applied Biosystems, Foster City, CA) and is specific for the
C. burnetii dotA gene. The forward and reverse primers are GCGCAATACGCTCAATCACA and CCATGGCCCCAATTCTCTT, respectively, and the probe sequence is CCGGAGATACCGGCGGTGGG. Purified plasmid DNA containing the
C. burnetii dotA gene was used as template to generate standard curves ranging form 10
3 to 10
8 plasmid copies.
Flow Cytometry
Human DC were harvested by incubation for 5 min in cold 0.1 M EDTA in PBS, followed by gentle scraping and centrifugation at 500 × g for 5 min at 4°C. The following monoclonal antibodies were used to characterize DC phenotypes: antiCD83-APC, antiCD86-PE, antiCD209-PerCP-Cy5.5, antiCD80-FITC, and antiCD11c-PE (BD PharMingen, San Diego, CA). Approximately 5 × 105 DC were stained with antibodies in FACS Wash (PBS, 2% FBS) for 15 min on ice, washed twice with FACS Wash and fixed with 4% paraformaldehyde. Samples were run on a FACS-Canto II flow cytometer (Becton Dickinson, San Jose, CA) and analyzed using FlowJo software (TreeStar, Ashland, OR).
Cytokine Assay
The concentrations of mouse IL-6 and TNF or human IL-1β, IL-6, IL-12p70 and TNF in culture supernatants were determined by BioPlex X-plex multiplex cytokine assay (BioRad, Hercules, CA) according to the manufacturers instructions.
Statistics
Statistical analysis was conducted to evaluate the significance between differences. The Student's t-test was used to compare the difference between groups. A p value of <0.05 was regarded as statistically significant.
Acknowledgements
We thank Shelly Robertson and Harlan Caldwell for critical review of the manuscript and Gary Hettrick and Anita Mora for graphic illustrations. This work was supported by the Intramural Research Program of the National Institutes of Health, National Institute of Allergy and Infectious Diseases (J.G.S., D.C.C, and R.A.H.), NIH grant AI052343 (K.T.), and NIH grants HL56068, HL52886, DE016191 and DE017821 (G.A.S.).
Authors' contributions
JGS conceived the study, designed and conducted experiments and drafted the manuscript. DCC participated in study design and carried out qPCR assays and animal work. GLS participated in experimental design and animal work. KT generated knock-out mice used in the study. RAH participated in study design and coordination and helped to draft the manuscript. All authors read and approved the final manuscript.