Bactericidal activity of avian complement: a contribution to understand avian-host tropism of Lyme borreliae

Concerning avian species, reservoir competence has been experimentally proven in several transmission studies [5,6,7,8,9,10] as well as in field studies in which feeding larvae were collected from avian hosts [5, 11, 12]. Under the assumption that transovarial transmission of B. burgdorferi s.l. is very rare in ixodid ticks [13], infections in fed larvae collected from birds captured in the field have been used as a proxy of reservoir host competence. In addition, serum susceptibility may also provide information on potential vertebrate reservoir hosts. Studies aiming at determining serum susceptibility have been performed for several vertebrates including avian, reptilian, rodent, and ruminant hosts (reviewed in [2]). Interestingly, data gathered from serum susceptibility studies with pheasants (Phasianus colchicus), blackbird (Turdus merula), seabird (unknown species), and quail (Coturnix sp.) indicated that (i) B. valaisiana and B. garinii are mainly resistant to avian complement, (ii) B. burgdorferi s.s. displayed an intermediate serum resistance phenotype, and (iii) B. afzelii, B. bavariensis, and B. lusitaniae were largely susceptible to avian sera (reviewed in [2] and [3]). These findings revealed a strong correlation between the ability of a particular Borrelia species to resist complement-mediated killing and its capability to infect and survive in the host from where the serum originates. Thus, rodent-associated genospecies are killed by avian serum whereby avian-associated genospecies are highly susceptible to rodent serum. Moreover, Passeriformes and gallinaceous bird species appeared to be capable of serving as reservoirs for B. garinii, B. valaisiana, and B. burgdorferi s.s. (hereafter referred to as B. burgdorferi), but not for B. afzelii, B. lusitaniae, B. japonica, and B. bavariensis.

The specific infection pattern supports the notion that complement is a driving factor for host tropism of Lyme borreliae. To gain further insight into the complement-host association pattern, we performed serum-bactericidal assays with avian sera collected from juveniles of four bird species captured in Portugal: European robin Erithacus rubecula (hereafter robin), great tit Parus major, Eurasian blackbird Turdus merula (hereafter blackbird), and racing pigeon Columba livia and four Borrelia species (B. afzelii, B. garinii, B. valaisiana, and B. burgdorferi). Our pilot study also aimed to better understand the findings on the reservoir competence of avian species for Lyme borreliae [6, 7, 14], in particular for those Borrelia genospecies commonly found in Europe.

Wild robins (n = 14), great tits (n = 16), blackbirds (n = 11), and racing pigeons (n = 9) were captured with mist nets from July to September 2019 in Vale Soeiro (40°19′ N, 8°24′ W), Portugal. We sampled blackbird, great tit, and robin juvenile birds (hatched in the previous breeding season). The sampled birds were ringed and carefully inspected for feeding ticks. Racing pigeons were sampled from a loft in Antanhol (40°09′ N, 8°27′ W), Coimbra, Portugal. None of the birds were infested with feeding ticks at the time of capture. In addition, cattle and goat serum were included as controls.

Blood was collected from the brachial vein into tubes containing clot activator (BD Microtainer tubes, Becton Dickinson, Spain, catalogue number 365967). The blood was immediately placed in a cool box until transport to the laboratory where it was centrifuged for 10 min at 14,000×g and 4 °C within a maximum of 9 h from collection. The serum was transferred into a new vial and frozen immediately at −80 °C until analyses.

Borrelia strains B. afzelii FEM1 (skin isolate, Germany), B. garinii G1 (CSF, Germany), B. valaisiana VS116 (type strain, tick isolate, Switzerland), B. burgdorferi B31 (ATCC^® 35210, tick isolate, USA), and B. lusitaniae PoHL (skin isolate, Portugal) were cultured until mid-exponential phase (5 × 10⁷ spirochetes per ml) at 33 °C in modified Barbour-Stoenner-Kelly (BSK-H) medium (Bio & Sell GmbH, Feucht, Germany).

The Borrelia strains used in this study have been selected for the following reasons: (i) they represent the most frequently isolated genospecies in ixodid ticks in Europe [5, 7, 11, 15], and (ii) the susceptibility/resistance pattern to human serum did not change in repeated studies. For instance, B. afzelii FEM1 always displayed a serum-resistant phenotype, B. garinii G1, B. valaisiana VS116, and B. lusitaniae PoHL were strongly serum-susceptible, and B. burgdorferi B31 could be categorized as intermediate serum-resistant [2]. In addition, the motility, viability, and morphology of each strain was inspected by dark-field microscopy to be sure that only highly viable spirochetes were used in the experiments.

For screening of anti-Borrelia IgG in the collected bird samples, a highly sensitive ELISA was used (Anti-Borrelia Plus VlsE ELISA IgG, EUROIMMUN, Lübeck, Germany) containing whole cell extracts of B. afzelii, B. garinii, and B. burgdorferi as well as recombinant OspC and VlsE. The protocol was performed according to the manufacturer’s recommendation except that sera were diluted 1:20 prior testing. Calibrators, standards, and the serum samples were added to the wells, and microtiter plates were incubated for 30 min at room temperature. After washing, antigen–antibody complexes were detected after an incubation of 30 min by using horseradish peroxidase (HRP)-conjugated goat anti-bird IgG antibody (abcam, Cambridge, UK) (dilution 1:50,000). Afterwards, the ready-to-use substrate was added, and the reactions were terminated after an incubation period of 15 min. The absorbance was measured at 450 nm. The final interpretation of the test results are as follows: values < 0.8 were negative, values between ≥ 0.8 < 1.1 are borderline, and values ≥ 1.1 were considered positive.

Serum susceptibility of spirochetes to bird sera was assessed as previously described with slight modifications [16]. Briefly, spirochetes grown at mid-logarithmic phase were sedimented by centrifugation, resuspended in 500 µl BSK medium, and counted by dark-field microscopy. Reaction mixtures consisting of 20 µl of highly viable spirochetes (4 × 10⁷ cells per ml) and 20 µl of avian serum were incubated at 38 °C with gentle agitation (350 rpm). The percentage of viable spirochetes was determined by dark-field microscopy after 0, 3, and 6 h. Spirochetes in nine microscopy fields were counted for each time point per strain and serum sample using Glasstic slides 10 (KOVA International Inc., CA, USA). Due to the small amount of blood collected from the individual bird, each Borrelia species was tested against serum samples of three different individuals of each bird species (except blackbird, n = 2). Of note, five out of seven serum samples collected from blackbirds showed haemolysis which leads to an agglutination of spirochetes immediately after adding to the reaction mixture (data not shown). The respective serum resistance pattern was defined according to the spirochetes’ motility and classified as follows: serum-resistant phenotype, 75–100% of viable spirochetes; intermediate serum-resistant phenotype, 30–75% of viable spirochetes; serum-sensitive phenotype, 0–30% of viable spirochetes [17]. The percentages of viable spirochetes were calculated by setting the number of motile bacteria at 0 h of incubation to 100%. Data were visualized by using GraphPad Prism version 7.04. Means are presented with standard deviation (SD).

To determine complement activity of the collected serum samples, the reptile-associated genospecies B. lusitaniae was employed. Due to the limited number of bird sera, only a single serum sample from P. major was analysed. As further controls, all Borrelia strains investigated were also exposed to cattle and goat sera, and viable spirochetes were counted after 3 and 6 h as described above.

To further assess to role of complement as a factor involved in avian-host association of Lyme borreliae, we investigated blood samples from juvenile birds, including two individual blackbirds, 12 great tits, 12 robins, and six racing pigeons. In addition, all serum samples investigated were screened for the presence of anti-Borrelia IgG antibodies. None of the serum samples tested were anti-Borrelia-positive except two serum samples collected from blackbirds, both of which were considered borderline (0.83 and 0.99, respectively).

Serum susceptibility testing was conducted by counting viable spirochetes by dark-field microscopy after an incubation period of 0, 3, and 6 h, as previously described [16]. As demonstrated in Fig. 1a, B. garinii G1, B. valaisiana VS116, and B. burgdorferi B31 displayed a resistant or an intermediate serum-resistant phenotype to all bird species investigated (mean percentage of viable spirochetes after 6 h of incubation: 75 ± 15%, range = 42–97%). The data show that B. afzelii FEM1 resists complement-mediated killing when individual serum samples from great tits and robins were employed (mean percentage of motile spirochetes after 6 h of incubation with great tit and robin sera: 84 ± 13%). By contrast, when B. afzelii FEM1 was exposed to serum samples of blackbirds, an average of 66 ± 7% spirochetes had been killed after 3 h of incubation, and only 16 ± 9.6% of spirochetes survived serum treatment after 6 h (Fig. 1b).

Serum susceptibility of Lyme borreliae exposed to bird serum samples. a Each genospecies and the respective avian species was independently challenged with serum samples from three individual birds, except for the sera of Eurasian blackbirds (Turdus merula, n = 2). b Percentage of viable spirochetes after 6 h of incubation with avian sera. The data represents three independent experiments for each Borrelia genospecies/bird species combination

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Of note, all four Borrelia species survived in the presence of serum collected from racing pigeons (85 ± 6.5% of motile spirochetes after 6 h of incubation). The highest survival rates after 6 h of incubation was observed for B. garinii G1 treated with blackbird serum (94 ± 2.9%) and B. afzelii FEM1 incubated with serum of the great tit (93 ± 8.8%) (Fig. 1b). Employing dark-field microscopy, only 6.5% of the cells of B. lusitaniae PoHL survived, while 94% of the cells of B. burgdorferi B31 resist complement-mediated killing after 6 h of incubation in the presence of great tit serum (data not shown). This finding indicates that avian complement was still active after blood collection and long-term storage. Furthermore, all Borrelia strains challenged with cattle and goat serum were efficiently killed after 6 h of incubation (Fig. 2) as previously described [18, 19].

Bactericidal effect of control sera on the viability of Lyme borreliae. Each Borrelia species was treated with serum samples collected from cattle (n = 1) and goat (n = 1). Three independent technical replicates (E1 to E3) were performed

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Emphasizing the potential impact of complement as an important factor determining host tropism of Lyme borreliae, here we analysed the serum susceptibility of the four main Borrelia genospecies in Europe to sera collected from juvenile wild birds. For comparison, and apart from blackbirds [3], we included great tits and robins, two wild ubiquitous bird species often infested with ixodid ticks [11, 20], and the racing pigeon as potential host for Lyme borreliae. The comparative analyses of our pilot study largely reiterate prior findings that avian-associated Borrelia species such as B. garinii and B. valaisiana resist complement-mediated killing to all serum samples analysed [3, 4, 21]. B. burgdorferi has previously been shown to resist complement-mediated killing by avian serum collected from pheasants and quail, both of which are utilized as model organisms for elucidating host association of Lyme borreliae [8, 21, 22, 23]. As expected, growth of B. afzelii FEM1 was strongly affected by blackbird serum as also demonstrated in previous studies in which pheasants (Phasianus colchicus), blackbirds, and a seabird were examined [3]. In contrast to previous findings, our data revealed for the first time that B. afzelii appears to survive in the presence of serum of robins, great tits, and racing pigeons, suggesting a species-specific host association/tropism of certain Borrelia species as discussed more recently for B. burgdorferi and B. bavariensis [2, 24].

Although numerous field studies and transmission experiments suggested that birds including great tits and robins play a limited or even a negligible role in maintaining B. afzelii in circulation [5, 6, 25], previous findings of B. afzelii-infected larvae and nymphs that fed on birds revealed that certain bird species, including great tits [11, 26], robins [14], dunnocks, and song thrushes [6], might serve as potential reservoir hosts or transmitters for certain B. afzelii strains and variants, respectively [14, 15]. B. afzelii-infected larvae could result from co-feeding or incomplete blood meal on another infected vertebrate host [15]. In addition, Heylen et al. [6] found that pathogen-free larval Ixodes ricinus ticks co-feeding with B. afzelii-infected I. ricinus nymphal ticks on naive blackbirds did not become infected with B. afzelii, but a low percentage of infected larvae were detected when this experiment was performed in naïve great tits. These findings suggest that avian blood of naïve great tits and blackbirds was bactericidal to particular B. afzelii strains or variants and, thus, provide additional evidence for a strain-specific host association. It is tempting to speculate that the concept of a restricted genospecies-specific host association of Lyme borreliae (i.e., division into rodent-associated, avian-associated, and reptile-associated genospecies) has to be readjusted, in particular due to recent observations revealing more diverse relationships of Lyme borreliae with their hosts in nature as previously thought.

Concerning B. garinii and B. valaisiana, both genospecies have predominately been identified in ticks collected from ground-dwelling and migrating songbirds such as tree pipits, blackbirds, great tits, robins, and song thrushes, revealing a strong association of these Borrelia genospecies with distinct avian hosts [15]. In line with these findings, we showed that B. garinii and B. valaisiana exhibited an intermediate serum-resistant or serum-resistant phenotype to the sera of all four wild birds tested in our study (Fig. 1).

In contrast to the United States where B. burgdorferi is the main Borrelia species causing Lyme disease [27, 28, 30, 31], the competence of birds as reservoir hosts has not fully been elucidated in Europe [29]. Here, we showed that B. burgdorferi displayed either an intermediate serum-resistant (robin) or a serum-resistant (blackbird, great tit, and racing pigeon) phenotype to avian sera (Fig. 1). These findings are also in close agreement to the data obtained from previous serum bactericidal assays demonstrating that B. burgdorferi was partially resistant to blackbird, pheasant, and seabird sera [3, 4]. In summary, our data suggest that Borrelia-specific factors along with the avian innate immune system contributes to host speciation and competence as proposed recently [2].

The racing pigeon is thought to have a negligible or even a minor role in the B. burgdorferi s.l. transmission cycle, as those birds are largely maintained in captivity. Nevertheless, free-living pigeons are known to carry several zoonotic pathogens [32] and, thus, may contribute to the circulation of certain pathogens. Further investigations aiming at elucidating the reservoir competence of free-living pigeons will undoubtedly complement our findings indicating that serum of pigeons did not exhibit a borreliacidal effect on spirochetes; thus a potential role of this bird species in B. burgdorferi s.l. transmission cannot be completely discounted.

All serum samples analysed derived from birds that were captured in the wild, except for the sera collected from racing pigeons. Although none of the birds were infested with ticks at the time of capturing, we cannot completely rule out that they have had previous contact with Borrelia-infected ticks. However, those were juvenile birds, born in the previous spring, and the tick activity in this region is relatively low during warm and dry summer months [20], reducing the probability of contact of these birds with questing ticks. In addition, serological tests confirmed that none of the sera investigated were positive for anti-Borrelia IgG antibodies except the two samples collected from blackbirds showing a borderline result. Of note, B. afzelii FEM1 also displayed a serum-sensitive phenotype when an anti-Borrelia-negative blackbird sample was used for the bactericidal assays (data not shown). This finding suggested that B. afzelii FEM1 was primarily killed by the activation of the alternative pathway, but not through an antibody-dependent complement activation via the classical pathway. Also, the data of the serum bactericidal assays presented herein revealed a high consistency when different individual sera were tested with a given Borrelia species, suggesting that those birds were likely naïve.

Although serum complement is a limiting factor affecting Borrelia survival in the tick and directly after transmission to the vertebrate host, the inferences on vertebrate reservoir competence should take into consideration additional factors such as the heterogeneity of proteins interacting with the host immune system among individual Borrelia strains as well as host-specific factors like the physiological state and age of the birds that also may affect the host’s competence. Moreover, genetic polymorphism among avian host populations cannot be excluded because co-evolution between host and spirochetes might also contribute to a strain-specific serum susceptibility pattern. In summary, the data presented herein not only confirm previous findings but add new data on the complexity of a complement-driven host tropism among Borrelia in nature.