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Volume 26, Number 4—April 2020
Dispatch

Detection of Zoonotic Bartonella Pathogens in Rabbit Fleas, Colorado, USA

Author affiliations: Nihon University College of Bioresource Sciences, Fujisawa, Japan (S. Sato, S. Funada, S. Maruyama); University of Richmond, Richmond, Virginia, USA (R.J. Brinkerhoff, E. Hollis, A.B. Shannon); University of KwaZulu-Natal, Pietermaritzburg, South Africa (R.J. Brinkerhoff)

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Abstract

We detected 3 Bartonella species in wild rabbit fleas from Colorado, USA: B. vinsonii subsp. berkhoffii (n = 16), B. alsatica (n = 5), and B. rochalimae (n = 1). Our results support the establishment of the zoonotic agent B. alsatica in North America.

Wild lagomorphs (rabbits, hares, and pikas) are known or potential reservoirs for a number of zoonotic agents, including tularemia (Francisella tularensis), plague (Yersinia pestis), pasteurellosis (Pasteurella multocida), ringworm (Trichophyton spp.), and cryptosporidiosis (Cryptosporidium cuniculus) (1). In 1999, a novel Bartonella species, B. alsatica, was isolated from the blood of wild rabbits (Oryctolagus cuniculus) in eastern France (2). B. alsatica was later identified as a causative agent of lymphadenitis (3) and endocarditis (4,5) in humans. A case of prosthetic vascular graft infection caused by B. alsatica was reported in 2019 (6).

The geographic distribution of B. alsatica is poorly understood, as is its mode of transmission, although vector-mediated transmission was suggested upon initial characterization of this agent (2). B. alsatica DNA has been detected in fleas collected from Bartonella-infected wild rabbits in France (7) and Spain (8,9), suggesting the potential for fleaborne B. alsatica transmission. Our goal was to describe associations between rabbit-associated Bartonella and potential flea vectors in the United States to gain insights into transmission of fleaborne zoonoses.

The Study

We collected fleas from live-trapped desert cottontail rabbits (Sylvilagus audubonii) in June and July 2005 from 8 sites in Boulder County, Colorado, USA (10). We identified fleas to species by light microscopy using dichotomous keys (10) and then stored them in 96-well tissue culture plates at −20°C, except for representatives of each species that were removed and submitted to the Centers for Disease Control and Prevention (Fort Collins, CO, USA). In 2015, we extracted DNA from individual fleas using commercial DNA extraction kits (Blood and Tissue Kit; Macherey-Nagel, Inc., https://www.mn-net.com), with aliquots of extracted DNA maintained at the University of Richmond (Richmond, VA, USA), and secondary aliquots sent to the Laboratory of Veterinary Public Health, Nihon University College of Bioresource Sciences (Fujisawa, Japan). Both laboratories screened samples for Bartonella infection by conventional PCR targeting part of the ssrA gene; primers used were ssrA-F (5′-GCTATGGTAATAAATGGACAATGAAATAA-3′) and ssrA-R (5′-GCTTCTGTTGCCAGGTG-3′). The targeted gene was selected because of the robustness of the PCR assay and the ability of the locus to segregate Bartonella at the species level (11). Nihon University College of Bioresource Sciences also used real-time PCR targeting the ssrA gene to confirm Bartonella species for those samples. This PCR used a genus-specific TaqMan probe, 6-carboxyfluorescein (FAM)–labeled probe (5′-FAM-ACCCCGCTTAAACCTGCGACG-3′-BHQ1, where BHQ is black hole quencher); primers were the same as for conventional PCR. Samples that tested positive for Bartonella DNA by real-time PCR and for which unambiguous sequence data were collected in both laboratories from the target locus (ssrA) were reported as Bartonella positive. We sequenced all amplicons (301 bp) from conventional PCR and aligned them with Bartonella type strains and then subjected them to phylogenetic analysis using MEGA 7.0 (https://www.megasoftware.net).

We collected 141 fleas from 14 desert cottontail rabbits (average fleas per parasitized host 14.3, range 1–54) in the summer of 2005. Of these fleas, 105 (81 Euhoplopsyllus glacialis and 24 Cediopsylla inaequalis) collected from 7 rabbits sampled at 4 sites (Table 1; specific site locations in 10) were available for molecular screening for Bartonella. The remaining 36 fleas were processed for Yesinia pestis surveillance in a separate project (R.J. Brinkerhoff et al., unpub. data) and were not available for Bartonella testing.

Figure

Thumbnail of Phylogenetic relationships of Bartonella ssrA sequences detected in study of zoonotic Bartonella in rabbit fleas, Colorado, USA, compared with reference sequences. This tree was generated based on 253 bp by maximum likelihood and 1,000 bootstrap replicates using the Kimura 2-parameter evolutionary model with gamma-distributed rates among sites. Sample numbers are found in Table 2. GenBank accession numbers are indicated. Scale bar indicates nucleotide substitutions per site.

Figure. Phylogenetic relationships of Bartonella ssrA sequences detected in study of zoonotic Bartonella in rabbit fleas, Colorado, USA, compared with reference sequences. This tree was generated based on 253 bp by maximum...

We detected Bartonella DNA in 2 (8.3%) C. inaequalis fleas collected from 1 rabbit (ID no. 522) and 21 (25.9%) E. glacialis fleas collected from 5 rabbits (ID nos. 305, 522, 633, 673, and 674) (Table 1). All nucleotide sequences matched closely to 3 zoonotic Bartonella species, B. alsatica, B. vinsonii subsp. berkhoffii, and B. rochalimae (Table 2), and clustered phylogenetically with reference sequences of the type strains with high bootstrap support (Figure). The representative sequences of the 3 Bartonella species were registered in International Nucleotide Sequence Database Collaboration with accession nos. PS522-c9 (GenBank accession no. MN654366), PS674-e5 (GenBank accession no. MN654366), and PS674-e6 (GenBank accession no. MN654366). All 3 rabbits (ID nos. 522, 633, 674) from which >1 flea was PCR-positive and available for sequencing produced multiple Bartonella species (Table 2).

Conclusions

We detected DNA of 3 zoonotic Bartonella species among the 105 rabbit fleas we tested for this study; overall Bartonella prevalence in fleas was 21.9% (23/105), which is comparable to previous prevalence estimates from rabbit fleas in Europe (7,9). This study had several noteworthy findings: B. alsatica DNA was detected in North America, and carnivore-associated Bartonella species occurred in rabbit fleas. These findings highlight the complexity of pathogen–vector–host associations and demonstrate why vector ecology is necessary for elucidating the evolution and enzootic transmission of vectorborne pathogens. Since B. alsatica was described in 1999 (2), its DNA has been detected not only in European rabbits (Oryctolagus cuniculus) in Spain (8) but also in rabbit fleas (Spilopsyllus cuniculi and Xenopsylla cunicularis) collected in France (7) and Spain (9) and has been associated with human disease in France (36). In 2019, detection of B. alsatica DNA was reported in cat fleas (Ctenocephalides felis) infesting cats and dogs in the United Kingdom (12).

A recent study reported ftsZ and nuoG sequences with ≈95% similarity to B. alsatica from the spleens of spiny rats (Thrichomys fosteri) in Brazil (13), the only previous published report of B. alsatica in the Americas. The B. alsatica sequences in our study were more similar to the B. alsatica type strain than were the putative B. alsatica sequences detected in Brazil. However, the B. alsatica sequences in our study were not identical to the type strain, suggesting that divergent B. alsatica strains may be circulating in the Americas. Further sampling of lagomorphs and their ectoparasites throughout North and South America is necessary to determine the geographic extent of B. alsatica, as well as its genotypic variation and evolutionary history.

We can conclude that both C. inaequalis and E. glacialis fleas are able to acquire Bartonella DNA and that blood-feeding is a likely mode of Bartonella acquisition, based on the observation that multiple fleas from the same host tested positive for Bartonella DNA. The detection of carnivore-associated Bartonella species in rabbit fleas was unexpected; typical reservoirs for B. rochalimae and B. v. subsp. berkhoffii are wild carnivores such as coyotes, foxes, raccoons, and skunks. However, B. rochalimae or B. rochalimae–like bacteria were found in the blood of brown rats (Rattus norvegicus) captured in Taiwan and in California, USA (14). Thus, B. rochalimae might have the potential to infect rodents as well as carnivores. Both rabbit flea species sampled in this study have been recovered from wild carnivore species in our study system and thus could serve as bridge vectors between carnivores and rabbits (10). In Europe, rabbit fleas have also been collected from carnivores (15), suggesting potential lagomorph–carnivore B. alsatica transmission in other systems as well.

Yersinia pestis, another fleaborne zoonotic agent that periodically causes epizootic events in our system (10), may spill over into amplifying hosts from putative reservoirs (mammalian, flea, or both) or from environmental sources. Flea and Bartonella (Table 2) exchange between lagomorphs and carnivores suggests that Y. pestis could also jump among these groups of mammals. Moreover, desert cottontails co-occur with black-tailed prairie dogs (Cynomys ludovicianus), a species associated with epizootic Y. pestis emergence, and flea exchange between desert cottontails and prairie dogs has been described (10). Given our findings, it is apparent that desert cottontail rabbits are associated with multiple zoonotic Bartonella species, including B. alsatica, which had not been previously recorded in North America, and that wild lagomorphs may contribute to the maintenance and transmission of several vectorborne zoonoses.

Dr. Sato is an assistant professor in the Department of Veterinary Medicine, College of Bioresource Sciences, Nihon University, Fujisawa, Japan. His primary research interests are the epidemiology of bartonellosis, bacterial ecology in wildlife, and control of bacterial zoonoses.

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Acknowledgments

All wildlife sampling was conducted with approval from the Institutional Animal Care and Use Committee at the University of Colorado-Boulder.

Funding for this project was provided in part by a Weinstein grant from the University of Richmond to S.S. and R.J.B., by a Fulbright Scholar Award to R.J.B., and by National Science Foundation grant no. EF0224328. This project was also supported by a University of Richmond Arts and Sciences Summer Fellowship to A.B.S. Additional funding was provided by Nihon University College of Bioresource Sciences.

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References

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Cite This Article

DOI: 10.3201/eid2604.191161

Original Publication Date: March 09, 2020

1These authors contributed equally to this article.

Table of Contents – Volume 26, Number 4—April 2020

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R. Jory Brinkerhoff, University of Richmond Department of Biology, 28 Westhampton Way, Richmond, VA 23173, USA

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Page created: March 17, 2020
Page updated: March 17, 2020
Page reviewed: March 17, 2020
The conclusions, findings, and opinions expressed by authors contributing to this journal do not necessarily reflect the official position of the U.S. Department of Health and Human Services, the Public Health Service, the Centers for Disease Control and Prevention, or the authors' affiliated institutions. Use of trade names is for identification only and does not imply endorsement by any of the groups named above.
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