A total of 705 rodents were captured. The number of rodents tested and infectivity rates at different survey sites are shown in the Table. A. phagocytophilum was detected only in rodents captured in eastern regions of China (Heilongjiang, Jilin, and Zhejiang provinces) (Figure). B. burgdorferi was detected in rodents captured at all 6 survey sites. SFG rickettsiae were detected in rodents captured at all sites except Jilin Province. F. tularensis was detected in rodents captured only in northern China (Heilongjiang and Jilin provinces and Inner Mongolia and Xinjiang autonomous regions; Figure).

In Heilongjiang Province, all 4 agents were detected in rodents at similar frequencies (χ² 2.80, df 3, p = 0.424). No SFG rickettsiae were detected in rodents from Jilin Province. The infectivity rates for the 3 agents in Jilin Province did not significantly differ (χ² 2.23, df 2, p = 0.328). Infectivity rates for SFG rickettsiae were significantly higher than those for B. burgdorferi and F. tularensis in rodents from Inner Mongolia Autonomous Region (χ² 39.76, df 2, p<0.001). Infectivity rates for the 3 agents in Xinjiang Autonomous Region did not differ significantly (χ² 5.01, df 2, p = 0.082). Except for F. tularensis, the other 3 agents showed similar infectivity rates for Zhejiang Province (χ² 1.30, df 2, p = 0.523). Only B. burgdorferi and SFG rickettsiae were found in Guizhou Province, and the difference in their infectivity rates was not significant (p = 0.525, by Fisher exact test).

A total of 18 (2.6%, 95% confidence interval 1.4%–3.8%) rodents from all survey sites except Xinjiang Autonomous Region were positive for 2 or 3 agents, among which 15 were positive for 2 agents. A Clethrionomys rufocanus rodent from Heilongjiang Province was positive for A. phagocytophilum, B. burgdorferi, and SFG rickettsiae, and 2 rodents (Apodemus agrarius and Tamias sibiricu) from Jilin Province were positive for A. phagocytophilum, B. burgdorferi, and F. tularensis (Appendix Table 1).

Overall, except for 6 unclassified rodents, 23 species of rodents captured at the 6 survey sites were identified. Rodent species composition varied greatly at different sites ( Appendix Table 2). Rattus norvegicus rodents were found at all survey sites except Xinjiang Autonomous Region. A. agrarius, A. peninsulae, Clethrionomys rufocanus, Mus musculus, and T. sibiricu rodents were found in northeastern China; A. sylvaticus, Niviventer confucianus, and R. losea were found mainly in southern China; and Meriones unguieulataus and M. musculus were found mainly in western China.

The dominant rodent species differed at various study sites. C. rufocanus (57.8%) was dominant in Heilongjiang Province, A. agrarius (36.2%) and A. peninsulae (27.1%) in Jilin Province, A. agrarius (29.7%) and Microtus maximowiczii (23.7%) in Inner Mongolia Autonomous Region, M. musculus (50.0%) and M. unguieulataus (34.1%) in Xinjiang Autonomous Region, N. confucianus (53,0%) in Zhejiang Province, and R. norvegicus (32.14%) and M. musculus (28.6%) in Guizhou Province ( Appendix Table 2).

To confirm the presence and determine genotypes of detected organisms, PCR products were sequenced and analyzed. A 919-bp partial 16S rRNA gene fragment for A. phagocytophilum was obtained from each positive specimen (8). A. phagocytophilum sequences detected in rodents from Heilongjiang and Jilin provinces (GenBank accession no. DQ342324) were identical and differed from those from Zhejiang Province (GenBank accession no. DQ458808) by 2 bp, from those from ticks in United Kingdom and Sweden (GenBank accession nos. AY082656 and AJ242784.1, respectively) by 2 bp, and from other known A. phagocytophilum sequences by >3 bp.

Sequence analysis of the B. burgdorferi 5S–23S rRNA intergenic spacer showed that agents isolated from rodents in Heilongjiang Province, Inner Mongolia Autonomous Region, Jilin Province, and Xinjiang Autonomous Region belonged to the B. garinii genospecies, similar to agents detected in ticks (GenBank accession no. DQ150540) in northern China. Of 16 B. burgdorferi detected in Zhejiang Province, 12 belonged to the B. garinii genospecies and the other 4 belonged to the B. valaisiana–related group (GenBank accession nos. EU160458 and EU160459). The 2 strains found in Guizhou Province also belonged to the B. valaisiana–related group (GenBank accession no. EU247840).

For identification of SFG rickettsiae, partial nucleotide sequences of the ompA gene were obtained from positive specimens in Heilongjiang Province and Inner Mongolia Autonomous Region. All sequences were identical to those of the R. sibirica genotype (GenBank accession no. U43807). Nucleotide sequences of 35 specimens positive for F. tularensis were identical to each other and to published sequences for the F. tularensis subsp. holarctica strain (GenBank accession no. AF247642.2).

We detected A. phagocytophilum, B. burgdorferi, SFG rickettsiae, and F. tularensis in diverse species of rodents from different areas of China. Our findings and previous evidence (6,9,12–15) suggest that several tick-borne agents cocirculate in mainland China, and a variety of rodent species may be involved in enzootic maintenance of these agents.

This study was not intended to be a comprehensive survey on active infections with A. phagocytophilum, B. burgdorferi, SFG rickettsiae, and F. tularensis. Rather, it was designed to investigate the presence and extent of these agents in China. If one considers that human infections with A. phagocytophilum, B. burgdorferi, SFG rickettsiae, and F. tularensis have been reported in various regions of China (16–19), the presence of these agents in rodents in the study areas suggests a potential threat to humans, and the public health role of these findings should be further investigated.

Although infectivity rates varied at different survey sites (Table, Appendix Table 1), we could not determine the geographic diversity of these agents in rodents. The number of rodents examined was limited; therefore, infectivity rates in the current study could be biased. In addition, because intensity of circulation of any vector-borne agent fluctuates dramatically throughout the year and from year to year, even at the same location (20,21), we could not justify comparing infectivity rates between different sites on the basis of unsynchronized single collections over a 3-year period. A randomized sampling scheme and further collection of rodents are required to clarify this issue. Unfortunately, we did not collect the ticks from captured rodents for additional testing of the tick-transmitted agents. This limitation prevented us from understanding vector potential.

In this study, A. phagocytophilum was detected only in eastern China (Table, Figure), where it coexists with the other 3 agents (Appendix Table 1). A. phagocytophilum detected in Heilongjiang, Jilin, and Zhejiang provinces were closely related to each other by 16S rRNA gene sequence analysis, but less related to other known strains in other countries. B. burgdorferi was detected in rodents from all 6 survey sites. As observed in a previous study (9), B. garinii was the dominant genospecies in mainland China, and the B. valaisiana–related group was present in southern China.

SFG rickettsiae, including ≈20 species of rickettsiae, can be transmitted to animals and humans not only by ticks but also by other arthropods such as infected lice, fleas, and mites (10). In this study, we amplified the ompA gene, which is present in most SFG rickettsiae (10,22). The overall infectivity rate for SFG rickettsiae was highest (9.1%) among the 4 agents tested (Appendix Table 1). Sequence analysis identified the Rickettsia sp. detected in Heilongjiang Province and Inner Mongolia Autonomous Region as a genotype of R. sibirica, which is known to cause Siberian tick typhus (18). However, we did not sequence PCR products amplified from rodents at other study sites because of a limited amount of samples. Although sequence analysis of the ompA gene fragment is not sufficient to identify the agent (22), it is commonly used to recognize tick-borne Rickettsia spp. in field surveys (23).

F. tularensis was found only in northern China, which verifies our belief that F. tularensis is present only north of 30°N latitude. In many disease-endemic areas, ticks are known to play a role in transmitting F. tularensis from animal hosts to humans, although other arthropods such as deer flies, fleas, mites, and mosquitoes are known to carry the bacterium. Sequence analysis showed that all F. tularensis detected in this study belong to the subspecies holarctica.

Interference of infections among A. phagocytophilum, B. burgdorferi, SFG rickettsiae, and F. tularensis in rodent hosts is not clear. Our findings indicate that infection with A. phagocytophilum does not intensify risk for transmission of the other 3 agents and vice versa. B. burgdorferi in rodents appears to increase risk for infection with F. tularensis but does not increase the possibility of infection with SFG rickettsiae or A. phagocytophilum. Further investigations are needed to demonstrate positive or negative interactions of the pathogens and to establish whether this interference is associated with the animal species.

Of 705 rodents tested in this study, 15 were infected with 2 agents and 3 were infected with 3 agents. These findings indicate that mixed natural foci of tick-borne agents are present at the study sites. Because A. phagocytophilum, B. burgdorferi, SFG rickettsiae, and F. tularensis were found in ticks collected in the study areas (6–9,12–14), it is not surprising that multiple agents were detected in rodents. Coexistence of multiple agents might be caused by a single bite of a tick infected with several agents or multiple bites of ticks infected with at least 1 agent. The presence of 4 pathogens in the study areas demonstrates the risk for multiple infections in humans, which may lead to variations and exacerbation of clinical signs (1). Therefore, differential diagnoses should be made for febrile patients with a history of tick bites in these areas, particularly when clinical signs are atypical for 1 disease or a related disease.

Among 23 rodent species trapped in this study, 21 were infected with >1 agent ( Appendix Table 2). Only 2 species (Cricetulus migratourius and N. fulvescens) were negative for all 4 agents. Which species is the main host of each agent remains unknown, because none of the agents are predominantly associated with 1 or a few related rodent species, regardless of their geographic origin. However, A. phagocytophilum, B. burgdorferi, SFG rickettsiae, and F. tularensis in various rodent species illustrate the potential roles of various rodents in maintaining these tick-borne agents. Systematic epidemiologic studies that investigate characteristics of natural foci and the role of small wild animals in transmission of these agents to humans are needed.