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Urban rodent reservoirs of Borrelia spp. in Warsaw, Poland

Published online by Cambridge University Press:  05 March 2018

A. Gryczyńska*
Affiliation:
Department of Ecology, Faculty of Biology, Institute of Zoology, Biological and Chemical Research Centre, University of Warsaw, 101 Żwirki i Wigury St., 02-089 Warsaw, Poland
T. Gortat
Affiliation:
Department of Ecology, Faculty of Biology, Institute of Zoology, Biological and Chemical Research Centre, University of Warsaw, 101 Żwirki i Wigury St., 02-089 Warsaw, Poland
M. Kowalec
Affiliation:
Department of Parasitology, Faculty of Biology, Institute of Zoology, University of Warsaw, 1 Miecznikowa St., 02-096 Warsaw, Poland
*
Author for correspondence: A. Gryczyńska, E-mail: [email protected]
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Abstract

The anticipated worldwide surge in urban environments is generating ever-greater interest in the study of host–pathogen interactions in this specific type of habitat. We investigated the potential of city-inhabiting rodents to serve as the main Lyme borreliosis agents (Borrelia spp.) reservoir. We also tried to verify if anthropogenic disturbances changing the vertebrate species community composition may also alter the scheme of Borrelia spp. circulation. A total of 252 Apodemus mice (A. agrarius, A. flavicollis, A. sylvaticus) were captured in Warsaw (Poland), at sites classified into different zones of anthropogenic disturbance, ranging from suburban forests to municipal parks strictly in the city centre. Borrelia spp. infection, ascertained based on bacterium DNA presence in the rodents’ blood, was found only in A. agrarius and A. flavicollis (7.6 and 6%, respectively). Only one species from the Borrelia genus – the mammal-associated species B. afzelii – was found in the mice studied. We found no statistical evidence of a correlation between infection in Apodemus mice and the zone of anthropogenic disturbance where the mice were caught. Non-homogeneous concentrations of Borelia spp. infected specimens within the strict city centre area suggest a lack of contact between members of particular mice subpopulations, and their responsibility for relatively high, but local Borrelia spp. infection.

Type
Original Paper
Copyright
Copyright © Cambridge University Press 2018 

Introduction

Lyme borreliosis (also known as Lyme disease) is a tick-borne zoonosis caused by spirochetes bacteria belonging to the Borrelia burgdorferi sensu lato complex. Among a dozen or so validly named species comprising this Borrelia complex that have been identified to date, ten infect humans (B. afzelii, B. bavariensis, B. bissettii, B. burgdorferi, B. garinii, B. kurtenbachii, B. lusitaniae, B. mayoni, B. spielmanii and B. valaisiana), causing a wide spectrum of clinical manifestations [Reference Margos1Reference Cutler3]. In terms of epidemiology, Lyme borreliosis is one of the most common and important diseases spread by ticks. The causative agents of Lyme borreliosis circulate between Ixodes ticks (in Europe mainly I. ricinus) and a large number of vertebrate hosts in an enzootic cycle. A tick must engorge on the blood of an infected vertebrate to acquire spirochetes, then become infected and be able to transmit them by feeding on another vertebrate to complete the cycle. Several dozen animal species can serve as Borrelia spp. potential reservoirs with small mammals, particularly rodents and insectivores, constituting the main group of vertebrates susceptible to maintaining the pathogen in nature [Reference Gern4]. Evidence has also been reported of ground-dwelling birds and lizards serving as competent reservoirs for this pathogen, although the role of birds and reptiles is relatively low as compared with that of mammals [Reference Gryczyńska5Reference Norte8].

The various reservoir groups are associated with different Borrelia species, due to the fact that they differ with respect to serum complement sensitivity [Reference Kurtenbach9, Reference Kurtenbach10]. The species B. afzelii was, until recently, regarded as a strictly rodent-connected group, appearing only in ticks feeding on mammals, mainly on small rodents, but not infective for birds [Reference Hanincová11]. Recent findings have altered this hypothesis, however, by showing that birds are also becoming carriers of ticks infected with this species, and in future presumably may establish a competent reservoir for it [Reference Dubska12Reference Gryczyńska and Welc-Falęciak14]. Currently, birds are considered as a competent reservoir hosts for B. burgdorferi, B. garinii, B. valaisiana and B. turdi [Reference Norte6, Reference Norte7, Reference Kempf15Reference Michalik17]. At the same time, the B. lusitaniae species is recognised to be associated with lizards [Reference Norte8, Reference Ekner18].

In this study, we sought to investigate the potential of small rodents to serve as the main Lyme borreliosis bacteria reservoir when living under the specific conditions typical of an urban habitat. In addition, we sought to elucidate whether anthropogenic disturbances which alter the composition of the vertebrate species community and limit their interactions are, thereby, capable of modifying the scheme of circulation and maintenance in the environment of the respective species of Borrelia spp.

Methods

Study area, mice collection

This study was performed in the city of Warsaw, Poland (52°12′N, 21°02′E; approx. 2 million residents) and surrounding non-urban areas. Small mammals were trapped at 10 locations situated in areas exhibiting different degrees of anthropogenic disturbance, at various distances from the city centre. Based on our previous research, we know that the city spatial structure (roads, buildings, etc.), urban infrastructure level and the percentage of the area covered by vegetation could influence the small mammal community composition [Reference Gortat19]. Rodent-trapping locations situated in the larger suburban forests and set-aside areas surrounding Warsaw, with relatively small anthropogenic disturbance, were classified into the Suburb Zone (S1–S5), whereas locations situated in municipal parks, squares and lawns in the city centre proper were classified into the Centre Zone (C1–C5) (Fig. 1). Nonetheless, all these areas are used intensively for recreational activity by Warsaw residents and their companion animals.

Fig. 1. Scheme of the study area (city of Warsaw, Poland) with the arrangement of mice-trapping locations. Black points – locations where Borrelia spp. infected mice were present; White points – locations where Borrelia spp. infected mice were not caught.

The trapping sessions were carried out for seven subsequent days in each location during September 2011 (at time of high rodent densities). At each location, a transect running about 600 m was delineated, along which live traps (two per point) for small mammals were set up every 20 m. Wheat grains and fruits were used as bait. The standard CMR method was used to trap the rodents. All captured mice (genus Apodemus) were individually marked and their species and sex were determined. A small volume (approx. 50 µl) of the rodents’ blood was obtained from the lateral tail vein and stored in vials containing EDTA buffer (our study was related to a broader project investigating the genetic structure of Warsaw-inhabiting rodents; as such, we gathered no data concerning tick densities in the habitat or mice infestation). After all these procedures the mice were released into the same habitats where they had just been caught. Individuals recaptured in subsequent days were released and were not rerecorded in the data analysis.

Laboratory procedures

Borrelia spp. infection was ascertained based on bacterium DNA presence in rodents’ blood [Reference Barbour20].

Genomic DNA was extracted using the AxyPrep Blood Genomic DNA Miniprep Kit (Axygen, USA) in accordance with the manufacturer's instructions. For further analyses the samples were stored at −20 °C.

All the samples were tested for the presence of Borrelia spp. DNA using the nested polymerase chain reaction (PCR) technique with Dream Taq polymerase and DreamTaq Green Buffer (Thermo Fisher Scientific Inc., USA), based on two-stage amplification of the fragment of the fla gene, coding for a bacterium flagellar protein (Thermal Cycler C1000; BioRad Laboratories, USA). The first-stage product was 774 base pairs in size, and the second-stage product was a 605 base-pair fragment of the fla gene. The thermal profiles and PCR primer sequences used in this study were those published [Reference Wodecka21], albeit slightly modified: initial denaturation at 95 °C for 5 min, denaturation at 95 °C for 30 s, annealing at 52 °C (I PCR) or at 55 °C (II PCR) for 30 s and then extending at 72 °C for 60 s for a total of 34 cycles in both of the stages, and also final elongation for 7 min. (I PCR 132f: 5′-TGGTATGGGAGTTTCTGG-3′, 905r: 5′-TCTGTCATTGTAGCATCTTT-3′; II PCR 220f: 5′-CAGACAACAGAGGGAAAT-3′; 824r: 5′-TCAAGTCTATTTTGGAAAGCACC-3′). DNA isolated from a Borrelia fla gene positive I. ricinus tick from Poland, sequenced and determined as B. afzelii was used as a positive control and a sterile water as a negative control. The second-stage products were separated by electrophoresis in 1.5% agarose gel in TAE buffer and visualised with Midori Green stain (Nippon Genetics, Germany) in UV light, wavelength 300 nm (BioRad Laboratories, USA).

Amplicons were purified using the Axygen Clean-up purification kit (Axygen, USA) and sequenced (Genomed, Poland) in one direction using the internal primer 824r. In order to compare nucleotide sequences with data stored in GenBank databases (http://www.ncbi.nih.gov/Genbank/index.html), BLAST-NCBI programs were used (http://www.ncbi.nlm.nih.gov/BLAST/).

Results

A total of 252 rodents were caught: 157 striped field mice A. agrarius, 84 yellow-necked mice A. flavicollis and 11 wood mice A. sylvaticus.

We found Borrelia spp. infection in the striped field mouse and yellow-necked mouse with the prevalence of 7.6% (12/157) and 6% (5/84), respectively (together representing a total of 6.8% of all the mice captured; 17/252) (Table 1). Given that no wood mouse was found to be infected, and also in view of the small number of wood mouse specimens trapped, we decided to exclude this species from further analyses.

Table 1. Borrelia spp. infection in Apodemus mice, by zones of anthropogenic disturbance, Warsaw, Poland

No statistically significant differences were found in the infection rate depending on mouse species (χ 2 = 0.24; DF = 1; P = 0.63). Moreover, neither in the striped field mice nor in yellow-necked mice did we find any statistically significant differences in Borrelia spp. infection depending on mouse sex (χ 2 = 1.97; DF = 1; P = 0.16 and χ 2 = 0.87; DF = 1; P = 0.35).

Examining the prevalence of Borrelia spp. infection in Apodemus mice populating particular green areas within the city of Warsaw, we found no statistical evidence of a correlation between this parameter and zone of anthropogenic disturbance where the mice were caught (χ 2 = 0.53; DF = 1; P = 0.47). Seven out of 10 trapping locations were populated by the infected mice (Fig. 1). All of the sites situated in the Suburb Zone were inhabited by these specimens. In contrary, mice living only at two (C1 and C2) out of five locations with the greatest anthropogenic disturbance, strictly in the city centre (Centre Zone), were Borrelia spp. infected (Table 1).

All the mice found to be infected in our study carried only a single species from the Borrelia genus – the rodent-associated B. afzelii. Using BLAST and phylogenetic analyses (MEGA 7.0) of a 563 bp fragment of the fla gene, among 17 B. afzelii sequences obtained in the study, we detected seven variants of nucleotide sequences (Table 2). The nucleotide identity/similarity of the fla gene fragments of the obtained B. afzelii sequences was very high (99.6–100%). One most frequent variant (A1) present in either A. agrarius or A. flavicolis was identical with five reference B. afzelii sequences in GenBank from A. agrarius (KF894064, KF894070), Myodes glareolus (KF894068) and Ixodes ricinus (KX646195, DQ016619) from Poland. Other variants (B1–B6) were highly similar, although single amino-acid substitution occurred in three sequences. The obtained sequences were deposited in GenBank (Table 2).

Table 2. Variants of fla gene sequences obtained in this study

Discussion

The anticipated worldwide surge in areas of urbanisation and intensive growth in the population of humans residing in large agglomerations could lead to alterations in wildlife–pathogen interactions in the near future [Reference Bradley and Altizer22Reference Hamer, Lehrer and Magle24]. As a habitat becomes altered by urbanisation, its composition of species and their biology usually change. To verify the potential impact of anthropogenic disturbances on pathogen maintenance, we resolved to carry out our study in an urban environment, seeking to ascertain whether the scheme of Borrelia spp. (B. burgdorferi sensu lato complex) circulation in these specific circumstances differs from that known in natural habitats.

Given that other research carried out in the city of Warsaw, at sites from suburban areas towards the urban core, documented a relatively high proportion of host-seeking Borrelia spp. infected I. ricinus ticks (6.1–23.5% [Reference Chmielewski25Reference Kowalec27]), the occurrence of infected vertebrates considered to be tick hosts and a competent reservoir for this bacterium was expected in our study in the Warsaw habitat. These animals not only participate in pathogen perpetuation, but also infect consecutive tick generations.

Previous studies showed that rodents belonging to the genus Apodemus may comprise a competent reservoir for Borrelia spp. bacteria in natural habitats uninfluenced by human activity. Not only was pathogen DNA found to be present in the investigated mice tissues (with the prevalence of 4.3–11%), but they were also found to have the ability to infect tick larvae feeding on them [Reference Siński28Reference Pascucci31]. Our results confirmed that Apodemus mice can be infected in similar level and potentially serve as a reservoir of Borrelia spp. bacteria also in a large urban agglomeration. Our results also suggest no species-dependent differences in mouse involvement in pathogen circulation in the Warsaw environment.

Previous research and our current results have shown diversity in the habitation pattern and non-homogeneous concentrations of particular Apodemus species within the Warsaw area [Reference Gortat19]. In the larger suburban forests and set-aside areas surrounding Warsaw (Suburb Zone), all of the investigated mouse species are present, but the strict city centre (Centre Zone) is almost exclusively populated by the striped field mouse, and other mouse species were occasionally present. Furthermore, the three mouse species selected for our investigation are known to comprise in total 85% of the whole small mammal community dwelling in Warsaw [Reference Gortat19]. At the same time, voles (genus Microtus and Myodes) are occasionally encountered in suburban forests and set-aside areas, and they are absent in most urban green areas within the strict city centre. Consequently, the striped field mouse could potentially serve as the basic rodent member of Borrelia spp. competent reservoir in the most urbanised parts of Warsaw.

On the other hand, it has been clearly demonstrated that in natural habitats, the involvement of voles in Borrelia spp. maintenance is significantly greater than that of mice. Studies carried in Lithuania and Norway have found the yellow-necked mouse to be less efficient in transmitting Borrelia spp. to ticks than the bank vole (M. glareolus) and field vole (Microtus arvalis) [Reference Paulauskas29, Reference Radzijevskaja30]. Research in central Italy found the infection rates of Apodemus spp. mice and bank voles to be 6.93 and 11.9%, respectively [Reference Pascucci31]. The authors suggest species-specific differences in susceptibility to Borrelia spp. infections and a higher propensity of voles vs. mice to transmit the infection to feeding larvae as potential reasons for this variation.

Because voles decisively avoid the urban environment, this kind of habitat, therefore, lacks the most common vertebrate participants establishing a competent Borrelia spp. reservoir. As such, it would seem that this role may be acquired by other small rodent species – e.g. mice from the genus Apodemus, constituting both an I. ricinus tick host group and a competent reservoir for pathogens carried by them. Nevertheless, based on our results, the lack of voles in the study area did not entail any significant increase in the prevalence of Borrelia spp. infection in Apodemus mice as compared with infection levels ascertained for these species inhabiting natural woodlands [Reference Radzijevskaja30, Reference Pascucci31].

It is known from the literature that urban environments may promote pathogen transmission through increased host contact rates, and additionally across gradients of urbanisation the incidence of some zoonotic pathogens has been found to be highest in urban cores [Reference Hamer23, Reference Hamer, Lehrer and Magle24]. Our present results partly run counter to these hypotheses, because infected mice were found in all of the suburban locations, and only in two (close to each other) out of five sites placed in the city centre. But the infection prevalence in mice subpopulations living in these two locations was much higher than in suburban ones. So, we can expect that mice living there were in close liaison with each other and did not have contact with members of remaining subpopulations. Our previous studies showed that small mammals inhabiting cities are constricted in their mobility by the specific urban structure (street network, open areas, densely built-up areas). In the case of small rodents inhabiting Warsaw, the great spatial isolation and consequently the specific genetic structure has been shown to cause a lack of contact between members of particular subpopulations of the mammals populating the strict city centre [Reference Gortat32, Reference Gortat33]. This is the potential reason why even though striped field mice are present in relatively great densities in green patches located in the city centre proper, they are responsible only for local Borrelia spp. maintenance and circulation, and probably do not currently comprise the main pathogen reservoir in the Warsaw habitat as a whole.

We may, therefore, conjecture that other groups of vertebrates may be participating in this process, with greater involvement as compared with natural circumstances. In large agglomerations, the other wildlife vertebrates (ungulates, carnivores) able to fulfil the above roles are still relatively rare within the strict centre. Also, the densities of these species’ populations in suburbs are small compared to those encountered in natural habitats. Presumably, red squirrels (Sciurus vulgaris) and European hedgehogs (Erinaceuseuropaeus) commonly occurring in the city centre proper could serve as potential Borrelia spp. reservoirs. Furthermore, in urban habitats, as compared with natural ones, birds could become more important as competent Borrelia spp. reservoirs. Many species of passerine birds have adapted to the urban environment with great flexibility and are persistently present even in city centres. Considering their intensive and easy mobility, birds can act as transport vehicles for ticks among different green areas within the city. They are also potential disseminators of Borrelia spp. spirochetes in the urban habitat, either as carriers of infected ticks or as reservoir hosts of the pathogen [Reference Gryczyńska5, Reference Norte6, Reference Michalik17, Reference Gryczyńska, Barkowska and Siemiątkowski34, Reference Marsot35].

Based on the example of Warsaw, we can state that the distinctive wildlife community composition typical of urban ecosystems can alter host–pathogen interactions. A lack of certain important mammal species, or their occurrence at low abundances, may affect diversity in the circulation of particular Borrelia species as compared to the natural habitat. Mammal interactions and consequently pathogen transmission are also hindered by the specific city centre structure. Therefore, potential relative growth can be expected in the relevance of birds, in relation to other groups of vertebrates, in establishing a reservoir for Lyme borreliosis agents in the urban habitat. This, in turn, could lead to an increasing proportion of Borrelia spp. species associated with avian reservoir groups vs. species occurring in rodents. Medical reports have shown that the respective Borrelia species are known to be linked to different Lyme borreliosis processes and distinctive clinical manifestations [Reference Rudenko2].

To complete the data concerning the contribution of city-inhabiting vertebrates in the Borrelia spp. circulation scheme, studies should investigate other species of mammals and birds populating urban areas. This is very important given that green areas within the city are used as places of recreation and leisure by humans and their companion animals. Thus, the continual renewal of our understanding of the dynamics of host–pathogen interactions in the urban environment allows us to better understand the channels by which the disease spreads and consequently to better manage and limit the risk of Borrelia spp. exposure to humans, companion animals and wildlife.

Acknowledgements

Approval for all the procedures used in this study was obtained from the First Warsaw Local Ethics Committee for Animal Experimentation, no. 21/2010. We are grateful to Daniel J. Sax for language editing, to Dr Miłosława Sokół for her help with applying statistical methods and to Dr Robert Meronka for the work he put into preparing the scheme of the study area. This study was financed in part by the National Science Centre (Grant No. N N304 169539).

Declaration of interest

None.

References

1.Margos, G, et al. (2011) Population genetics, taxonomy, phylogeny and evolution of Borrelia burgdorferi sensu lato. Infection, Genetics and Evolution 11, 15451563. doi: 10.1016/j.meegid.2011.07.022.Google Scholar
2.Rudenko, N, et al. (2011) Updates on Borrelia burgdorferi sensu lato complex with respect to public health. Ticks and Tick-borne Diseases 2, 123128. doi: 10.1016/j.ttbdis.2011.04.002.Google Scholar
3.Cutler, SJ, et al. (2017) Diagnosing Borreliosis. Vector Borne Zoonotic Diseases 17, 211. doi: 10.1089/vbz.2016.1962.Google Scholar
4.Gern, L (2008) Borrelia burgdorferi sensu lato, the agent of lyme borreliosis: life in the wilds. Parasite 15, 244247. doi: 10.1051/parasite/2008153244.Google Scholar
5.Gryczyńska, A, et al. (2004) Borrelia burgdorferi sensu lato infection in passerine birds from the Mazurian Lake region (Northeastern Poland). Avian Pathology 33, 6975.Google Scholar
6.Norte, AC, et al. (2013) Blackbirds Turdus merula as competent reservoirs for Borrelia turdi and Borrelia valaisiana in Portugal: evidence from a xenodiagnostic experiment. Environmental Microbiology Reports 5, 604607. doi: 10.1111/1758-2229.12058.Google Scholar
7.Norte, AC, et al. (2013) Birds as reservoirs for Borrelia burgdorferi s.l. in Western Europe: circulation of B. turdi and other genospecies in bird-tick cycles in Portugal. Environmental Microbiology 15, 386397. doi: 10.1111/j.1462-2920.2012.02834.x.Google Scholar
8.Norte, AC, et al. (2014) The importance of lizards and small mammals as reservoirs for Borrelia lusitaniae in Portugal. Environmental Microbiology Reports 8, 16. doi: 10.1111/1758-2229.12218.Google Scholar
9.Kurtenbach, K, et al. (1998) Differential transmission of the genospecies of Borrelia burgdorferi sensu lato by game birds and small rodents in England. Applied and Environmental Microbiology 64, 11691174.Google Scholar
10.Kurtenbach, K, et al. (2002) Host association of Borrelia burgdorferi sensu lato – the key role of host complement. Trends in Microbiology 10, 7479.Google Scholar
11.Hanincová, K, et al. (2003) Association of Borrelia afzelii with rodents in Europe. Parasitology 126, 1120. doi: 10.1017/S0031182002002548.Google Scholar
12.Dubska, L, et al. (2009) Differential role of Passerine birds in distribution of Borrelia spirochetes, based on data from ticks collected from birds during the postbreeding migration period in Central Europe. Applied and Environmental Microbiology 75, 596602. doi: 10.1128/AEM.01674-08.Google Scholar
13.Franke, J, et al. (2010) Are birds reservoir hosts for Borrelia afzelii? Ticks and Tick-borne Diseases 1, 109112. doi: 10.1016/j.ttbdis.2010.03.001.Google Scholar
14.Gryczyńska, A and Welc-Falęciak, R (2016) Long-term study of the prevalence of Borrelia burgdorferi s.l. infection in ticks (Ixodes ricinus) feeding on blackbirds (Turdus merula) in NE Poland. Experimental and Applied Acarology 70, 381394. doi: 10.1007/s10493-016-0082-x.Google Scholar
15.Kempf, F, et al. (2011) Host races in Ixodes ricinus, the European vector of Lyme borreliosis. Infection, Genetics and Evolution 11, 20432048. doi: 10.1016/j.meegid.2011.09.016.Google Scholar
16.Hanincová, K, et al. (2003) Association of Borrelia garinii and B. valaisiana with songbirds in Slovakia. Applied and Environmental Microbiology 69, 28252830.Google Scholar
17.Michalik, J, et al. (2008) Prevalence of avian-associated Borrelia burgdorferi s.l. genospecies in Ixodes ricinus ticks collected from blackbirds (Turdus merula) and song thrushes (T. philomelos). International Journal of Medical Microbiology 298, 129138. doi: 10.1016/j.ijmm.2008.03.004.Google Scholar
18.Ekner, A, et al. (2011) Anaplasmataceae and Borrelia burgdorferi sensu lato in the sand lizard Lacerta agilis and co-infection of these bacteria in hosted Ixodes ricinus ticks. Parasite and Vectors 4, 182. doi: 10.1186/1756-3305-4-182.Google Scholar
19.Gortat, T, et al. (2014) The effects of urbanization – small mammal communities in a gradient of human pressure in Warsaw city, Poland. Polish Journal of Ecology 62, 163172.Google Scholar
20.Barbour, AG, et al. (2009) Niche partitioning of Borrelia burgdorferi and Borrelia miyamotoi in the same tick vector and mammalian reservoir species. American Journal of Tropical Medicine and Hygiene 81, 11201131. doi: 10.4269/ajtmh.2009.09-0208.Google Scholar
21.Wodecka, B, et al. (2009) Detectability of tick-borne agents DNA in the blood of dogs, undergoing treatment for borreliosis. Annals of Agriculturaland Environmental Medicine 16, 914. doi: http://www.aaem.pl/pdf/16009.pdf.Google Scholar
22.Bradley, CA and Altizer, S (2006) Urbanization and the ecology of wildlife diseases. Trends in Ecology & Evolution 22, 95102. doi: 10.1016/j.tree.2006.11.001.Google Scholar
23.Hamer, SA, et al. (2012) Wild birds and urban ecology of ticks and tick-borne pathogens, Chicago, Illinois, USA, 2005–2010. Emerging Infectious Diseases 18, 15891595. doi: 10.3201/eid1810.120511.Google Scholar
24.Hamer, SA, Lehrer, E and Magle, SB (2012) Wild birds as sentinels for multiple zoonotic pathogens along an urban to rural gradient in greater Chicago, Illinois. Zoonoses and Public Health 59, 355364. doi: 10.1111/j.1863-2378.2012.01462.x.Google Scholar
25.Chmielewski, T, et al. (2011) Ticks infected with bacteria pathogenic to humans in municipal parks in Warsaw. Przegląd Epidemiologiczny 65, 577581 (in Polish).Google Scholar
26.Sytykiewicz, H, et al. (2012) Molecular screening for Bartonella henselae and Borrelia burgdorferi sensu lato co-existence within Ixodes ricinus populations in central and eastern parts of Poland. Annals of Agricultural and Environmental Medicine 19, 451456. doi: https://www.ncbi.nlm.nih.gov/pubmed/23020038.Google Scholar
27.Kowalec, M, et al. (2017) Ticks and the city – are there any differences between city parks and natural forests in terms of tick abundance and prevalence of spirochaetes? Parasites and Vectors 10, 573. doi: 10.1186/s13071-017-2391-2.Google Scholar
28.Siński, E, et al. (2006) Abundance of wild rodents, ticks and environmental risk of Lyme borreliosis: a longitudinal study in an area of Mazury Lakes District of Poland. Annals of Agricultural and Environmental Medicine 13, 295300.Google Scholar
29.Paulauskas, A, et al. (2008) Diversity in prevalence and genospecies of Borrelia burgdorferi sensu lato in Ixodes ricinus ticks and rodents in Lithuania and Norway. International Journal of Medical Microbiology 298, 180187. doi: 10.1016/j.ijmm.2008.04.003.Google Scholar
30.Radzijevskaja, J, et al. (2013) The propensity of voles and mice to transmit Borrelia burgdorferi sensu lato infection to feeding ticks. Veterinary Parasitology 197, 318325. doi: 10.1016/j.vetpar.2013.06.008.Google Scholar
31.Pascucci, I, et al. (2015) Detection of Lyme Disease and Q fever agents in wild rodents in central Italy. Vector-Borne and Zoonotic Diseases 15, 404411. doi: 10.1089/vbz.2015.1807.Google Scholar
32.Gortat, T, et al. (2015) Anthropopressure gradients and the population genetic structure of Apodemus agrarius. Conservation Genetics 16, 649659. doi: 10.1007/s10592-014-0690-0.Google Scholar
33.Gortat, T, et al. (2016) The spatial genetic structure of the yellow-necked mouse in an urban environment – a recent invader vs. a closely related permanent inhabitant. Urban Ecosystems 20, 581594. doi: 10.1007/s11252-016-0620-7.Google Scholar
34.Gryczyńska, A, Barkowska, M and Siemiątkowski, M (2002) Analysis of Ixodes ricinus (L.) tick burdens in a resident passerine bird community in the Mazurian Lake region (Northeastern Poland). Acta Parasitologica 47, 5157.Google Scholar
35.Marsot, M, et al. (2012) Which forest bird species are the main hosts of the tick, Ixodes ricinus, the vector of Borrelia burgdorferi sensu lato, during the breeding season? International Journal for Parasitology 42, 781788. doi: 10.1016/j.ijpara.2012.05.010.Google Scholar
Figure 0

Fig. 1. Scheme of the study area (city of Warsaw, Poland) with the arrangement of mice-trapping locations. Black points – locations where Borrelia spp. infected mice were present; White points – locations where Borrelia spp. infected mice were not caught.

Figure 1

Table 1. Borrelia spp. infection in Apodemus mice, by zones of anthropogenic disturbance, Warsaw, Poland

Figure 2

Table 2. Variants of fla gene sequences obtained in this study