Abstract
We conducted a serosurvey of 230 persons in Maine, USA, who had been bitten by Ixodes scapularis or I. cookei ticks. We documented seropositivity for Borrelia burgdorferi (13.9%) and B. miyamotoi (2.6%), as well as a single equivocal result (0.4%) for Powassan encephalitis virus.
Keywords: Borrelia burgdorferi, Borrelia miyamotoi, bacteria, Ixodes scapularis, ticks, deer ticks, tick bites, Powassan virus, POWV, viruses, seroprevalence, vector-borne infections, zoonoses, meningitis/encephalitis, Maine, United States
Reports of Lyme disease in Maine, USA, have increased from a few cases in the late 1980s to 1,848 cases in 2017 (1), coinciding with range expansion of Ixodes scapularis ticks over the past 3 decades (2). The Maine Center for Disease Control reported the first 2 cases of hard-tick relapsing fever caused by Borrelia miyamotoi during 2016 and an additional 6 cases during 2017 (1). Hard-tick relapsing fever typically manifests as a nonspecific febrile illness (3,4). Han et al. (5) found a B. miyamotoi infection prevalence of 3.7% in adult I. scapularis ticks in Maine, ≈10-fold less than that for B. burgdorferi infection (50%, range 32%–65%) (6).
Powassan virus (POWV) encephalitis can have devastating complications and has infected 10 residents of Maine during 2000–2017. There are 2 variants of POWV with distinct enzootic cycles and tick vectors. Lineage 1 is transmitted by I. cookei ticks and lineage 2, sometimes referred to as deer tick virus, is transmitted by I. scapularis ticks (7). Both lineages are present in Maine (7), but lineage 1 has a lesser risk for transmission because human bites by I. cookei ticks are infrequent (8). One fatal Maine case was demonstrated to be caused by lineage 2 POWV (7). Although POWV infection prevalence in Maine I. scapularis ticks is low (0.7%–1.8%) (9), frequent exposure to I. scapularis bites (8) and rapidity of POWV transmission (i.e., POWV can be transmitted to vertebrates after only 15 min from onset of the tick bite) (10) raise concern.
Our objective was to determine the seroprevalence of B. burgdorferi, B. miyamotoi, and POWV to clarify the frequency of exposure to each of these pathogens in resi-dents of Maine, USA, who had been bitten by I. scapularis or I. cookei ticks. We also anticipated that a serosurvey might provide evidence of asymptomatic POWV infection or self-limited illness in a few persons, as reported elsewhere (11,12).
The Study
The Vector-Borne Disease Laboratory of the Maine Medical Center Research Institute provided a free, statewide tick identification service during 1989–2013 to monitor exposure to I. scapularis ticks during range expansion of this invasive vector of human and animal disease. Persons submitted ticks that they had removed from themselves, family members, and pets. As of 2014, 33,332 ticks representing 14 species were identified in Maine; I. scapularis ticks were predominant.
During 2014, we used our tick identification service database (2) to identify persons who had removed >1 attached I. scapularis or I. cookei tick(s) in the previous 5 years (2009–2013). We invited these persons to participate in a serosurvey to assess past exposure to B. burgdorferi, B. miyamotoi, and POWV. Family members who attended the clinic with these persons and who reported being bitten by ticks were also invited to participate. The study was approved by Maine Medical Center Institutional Review Board (Protocol #4222). Participants provided informed consent (assent for minors) and submitted 30 mL of blood. Blood was centrifuged at 3,500 rpm for 15 min. Serum aliquots were stored at −20°C and then shipped to testing laboratories.
Serologic testing for antibodies to B. miyamotoi was conducted at the laboratory of one of the authors (P.J.K.). An ELISA and confirmatory Western blot assay were used to detect serum reactivity to B. miyamotoi GlpQ protein (13). For the ELISA, serum samples were diluted 1:320 and a signal >3 SD above the mean of 3 B. miyamotoi–negative serum controls was considered positive for B. miyamotoi antibody. Serum samples were considered B. miyamotoi seropositive if ELISA IgG and Western blot IgG tests yielded positive results.
Serologic evidence of exposure to B. burgdorferi was detected by the standard 2-step ELISA and Western blot assay in the L2 Diagnostic Laboratory at Yale School of Medicine by one of the authors (H.D.). A reactive serum was defined as one that reacted to a dilution >1:100. All borderline or reactive serum was further characterized by Western blot immunoassay. Specimens were considered positive for B. burgdorferi exposure if the IgG immunoblot contained >5 of the 10 most common B. burgdorferi–associated bands (14).
Serologic testing for POWV was conducted by one of the authors (G.D.E.) by using a plaque-reduction neutralization test (PRNT) and a POWV–West Nile virus (WNV) chimeric virus (POWV–premembrane–envelope [prME]/WNV) assay as described (15). The specificity of the assay was determined by cross-neutralization studies, which demonstrated that antiserum raised against POWV efficiently neutralized chimeric POWV–prME/WNV but not WNV and that antiserum raised against WNV did not neutralize POWV–prME/WNV (15). Use of the chimeric POWV–prME/WNV assay virus enabled PRNT testing to be conducted on African green monkey kidney (Vero) cells according to standard procedures by using a 90% neutralization cutoff to be considered positive (15).
Of 230 enrolled persons, 190 were in our tick identification program database, and 40 were family members (Table 1). Among the 190 persons, 1 tick bite was from an I. cookei nymph, 13% of bites were from I. scapularis nymphs, and 86% of bites were from I. scapularis adult females. Engorgement of ticks ranged from slight (43%) to moderate (38%) to high (18%). Among the study population, 32 (13.9%) were seropositive for B. burgdorferi, 6 (2.6%) were seropositive for B. miyamotoi, and 2 (0.9%) were seropositive for both pathogens (Table 2). The serum of 1 person (0.4%) neutralized POWV at a titer of 1:20 and WNV at a titer of 1:10. We designated this serum as flavivirus positive. This person reported a history of neurologic illness for >1 year and a tick bite within the study year.
Table 1. Characteristics of residents bitten by blacklegged (deer) ticks (Ixodes scapularis) during 2009 and 2013 who participated in a serosurvey for antibodies against Borrelia burgdorferi, B. miyamotoi, and Powassan virus, Maine, USA, 2014*.
| Characteristic | No. (%) residents |
|---|---|
| Mailings and responses | |
| No. persons mailed | 1,253 |
| No. persons attending a clinic | 230 |
| No. database persons | 190 |
| No. persons from families of database persons |
40 |
| Clinic information | |
| Location | |
| Biddeford clinics: April 23 and 26, 21 towns | 31 (13.5) |
| Ellsworth clinics: Apr 18 and 19, 34 towns | 94 (40.9) |
| Rockland clinics: Apr 5 and 18, 21 towns | 32 (13.9) |
| Scarborough clinics: Apr 10 and 12, 36 towns |
73 (31.7) |
| Tick bite history and demographics of persons in database |
|
| Year tick submitted | |
| 2009 | 27 (14.2) |
| 2010 | 41 (21.6) |
| 2011 | 47 (24.7) |
| 2012 | 37 (19.5) |
| 2013 |
38 (20.0) |
| Tick species/stage | |
| Ixodes cookei nymph | 1 (0.5) |
| Ix. scapularis female | 164 (86.3) |
|
Ix. scapularis nymph |
25 (13.2) |
| Tick engorgement | |
| Slight | 82 (43.2) |
| Moderate | 73 (38.4) |
| Heavy |
35 (18.4) |
| Age, y, at time of bite | |
| Adults, range 19–84 | 168 (88.4) |
| Children, range 6–18 |
22 (11.6) |
| Sex | |
| M | 88 (46.3) |
| F |
102 (53.7) |
| Demographics of all persons at time of clinic visit | |
| Age, y | |
| Adults, range 18–90 | 215 (93.0) |
| Children, range 8–17 | 15 (7.0) |
| Race | |
| Not reporting | 3 (1.3) |
| American Indian/Alaska Native | 0 (0.0) |
| Asian | 2 (0.9) |
| Black or African American | 0 (0.0) |
| Hispanic or Latino | 1 (0.4) |
| Native Hawaiian/Pacific Islander | 0 (0.0) |
| White | 224 (98.7) |
| Sex | |
| M | 107 (46.5) |
| F | 123 (53.5) |
*Database persons refers to tick-bitten persons who had submitted their ticks to a tick identification program in Maine. Family of database persons were database person family members who reported being bitten by a blacklegged tick during 2009–2013.
Table 2. Seropositivity of tick-bitten persons for Borrelia burgdoferi, B. miyamotoi, and Powassan virus, Maine, USA, 2014*.
| Pathogen, antibody test result | No. (%) database persons, n = 190 | No. (%) family of database persons, n = 40 | No. (%) total, n = 230 |
|---|---|---|---|
| B. burgdorferi | |||
| Positive | 26 (13.7) | 6 (15.0) | 32 (13.9) |
| Negative |
164 (86.3) |
34 (85.0) |
198 (86.1) |
| B. miyamotoi | |||
| Positive | 4 (2.1) | 2 (5.0) | 6 (2.6) |
| Negative |
186 (97.9) |
38 (95.0) |
224 (97.4) |
| B. burgdorferi/B. miyamotoi | |||
| Positive | 2 (1.1) | 0 | 2 (0.9) |
| Negative |
190 (98.9) |
40 (100.0) |
228 (99.1) |
| Powassan virus | |||
| Positive | 0 | 1 (2.5) | 1 (0.4) |
| Negative | 190 (100.0) | 39 (97.5) | 229 (99.6) |
*Database persons refers to tick-bitten persons who had submitted their ticks to a tick identification program in Maine. Family of database persons were database person family members who reported being bitten by a blacklegged tick during 2009–2013.
Conclusions
Among residents of southern Maine with a history of I. scapularis tick bites, the percentage who were seropositive for B. burgdorferi was 5 times greater than that for B. miyamotoi (13.9% vs. 2.6%) and 35 times greater than the percentage of deer ticks infected with POWV (0.4%). Because our study population consisted of persons bitten by I. scapularis ticks (with engorgement ranging from slight to high), we expect seroprevalence to be greater in this group than in that of the general population. The B. burgdorferi seroprevalence of 13.9% in our study population was ≈1.5 times higher than the seroprevalence of 9.4% reported by Krause et al. (13) in healthy residents of southern New England. In contrast, the B. miyamotoi seroprevalence of 2.1% was comparable to the seroprevalence of 1%–3.9% reported by Krause at al. (4,13).
Of 1,854 cases of infection with Borrelia spp. reported in Maine in 2017, a total of 1,848 were attributed to Lyme disease and only 6 (0.3%) were attributed to B. miyamotoi (1). On the basis of a seroprevalence of ≈2% in this study and that B. miyamotoi might be transmitted by all tick stages, we believe that this disease is underdiagnosed in Maine (5). Our population was identified by history of tick exposure, rather than by symptoms. Our results therefore represent the relative frequency of exposure to these different agents rather than risk for illness.
Although the sensitivity and specificity of the 2-tier antibody assay for B. burgdorferi is better validated than those of the B. miyamotoi and POWV assays, the sensitivity and specificity of these assays are good (13–15). Nonetheless, our findings might represent overestimates or underestimates of actual exposure to these agents because of false-positive or false-negative results. These data provide evidence that humans are exposed to B. burgdorferi, B. miyamotoi, and POWV in Maine and help define the prevalence of human infection caused by each of these tickborne pathogens.
Acknowledgments
We thank Thomas Courtney and his Biddeford office staff; Cheryl Liechty, Mark Eggena, and staff of Pen Bay Medical Center (Rockport, ME); Robert Pinsky and staff of Ellsworth Internal Medicine (Ellsworth, ME); and staff of the Maine Medical Center Research Institute (Scarborough, ME) for providing space and administrative support for the serosurvey clinics. We also thank the staff at the Maine Medical Center Research Institute Vector-Borne Disease Laboratory for processing samples.
This study was supported by National Institute of Health grant 1R56AI114859-01 (P.J.K.), a generous gift from the Gordon and Llura Gund Foundation (P.J.K.), and the Maine Medical Center Neuroscience Institute Research Grant Program. Study data were managed by using REDCap electronic data capture, hosted at Tufts University (https://www.tuftsctsi.org/research-services/informatics/redcap-research-electronic-data-capture/).
Biography
Dr. Smith is director of the Division of Infectious Diseases, Maine Medical Center Research Institute, Scarborough, ME; professor of medicine at Tufts University School of Medicine, Boston, MA; and principal investigator at the Vector-Borne Disease Laboratory, Maine Medical Center. His major research interests include epidemiology and ecology of emerging vectorborne diseases (Lyme disease, babesiosis, anaplasmosis, and infections with POWV and Eastern equine encephalitis virus) and clinical recognition and diagnosis of emerging vectorborne diseases.
Footnotes
Suggested citation for this article: Smith Jr RP, Elias SP, Cavanaugh CE, Lubelczyk CB, Lacombe EH, Brancato J, et al. Seroprevalence of Borrelia burgdorferi, B. miyamotoi, and Powassan virus in residents bitten by Ixodes ticks, Maine, USA. Emerg Infect Dis. 2019 Apr [date cited]. https://doi.org/10.3201/eid2504.180202
References
- 1.Maine Center for Disease Control. Reportable infectious diseases in Maine, 2017 summary; 2018. [cited 2018 Sep 18]. https://www.maine.gov/dhhs/mecdc/infectious-disease/epi/publications/#annualreports
- 2.Rand PW, Lacombe EH, Dearborn R, Cahill B, Elias S, Lubelczyk CB, et al. Passive surveillance in Maine, an area emergent for tick-borne diseases. J Med Entomol. 2007;44:1118–29. 10.1093/jmedent/44.6.1118 [DOI] [PubMed] [Google Scholar]
- 3.Platonov AE, Karan LS, Kolyasnikova NM, Makhneva NA, Toporkova MG, Maleev VV, et al. Humans infected with relapsing fever spirochete Borrelia miyamotoi, Russia. Emerg Infect Dis. 2011;17:1816–23. 10.3201/eid1710.101474 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 4.Krause PJ, Fish D, Narasimhan S, Barbour AG. Borrelia miyamotoi infection in nature and in humans. Clin Microbiol Infect. 2015;21:631–9. 10.1016/j.cmi.2015.02.006 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 5.Han S, Lubelczyk C, Hickling GJ, Tsao JI. Transovarial transmission rate and filial infection prevalence of Borrelia miyamotoi from Ixodes scapularis collected from hunter-harvested white-tailed deer. Presented at: International Symposium on Tick-Borne Pathogens and Disease; Vienna, Austria; September 24–26, 2017. [Google Scholar]
- 6.Smith RP, Elias SP, Borelli TJ, Missaghi B, York BJ, Kessler RA, et al. Human babesiosis, 1995–2011, Maine, USA. Emerg Infect Dis. 2014;20:1727–30. 10.3201/eid2010.130938 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 7.Cavanaugh CE, Muscat PL, Telford SR III, Goethert H, Pendlebury W, Elias SP, et al. Fatal deer tick virus infection in Maine. Clin Infect Dis. 2017;65:1043–6. 10.1093/cid/cix435 [DOI] [PubMed] [Google Scholar]
- 8.Smith RP Jr, Lacombe EH, Rand PW, Dearborn R. Diversity of tick species biting humans in an emerging area for Lyme disease. Am J Public Health. 1992;82:66–9. 10.2105/AJPH.82.1.66 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 9.Robich RM, Lubelczyk C, Welch M, Henderson E, Smith RP Jr. Detection of Powassan virus (lineage II) from Ixodes scapularis collected from four counties in Maine. Poster LB-5175. Presented at: 66th Annual Meeting of the American Society of Tropical Medicine and Hygiene; Baltimore, MD, USA; November 5–9, 2017. [Google Scholar]
- 10.Ebel GD, Kramer LD. Short report: duration of tick attachment required for transmission of powassan virus by deer ticks. Am J Trop Med Hyg. 2004;71:268–71. 10.4269/ajtmh.2004.71.3.0700268 [DOI] [PubMed] [Google Scholar]
- 11.Frost HM, Schotthoefer AM, Thomm AM, Dupuis AP II, Kehl SC, Kramer LD, et al. Serologic evidence of Powassan virus infection in patients with suspected Lyme disease. Emerg Infect Dis. 2017;23:1384–8. 10.3201/eid2308.161971 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 12.El Khoury MY, Camargo JF, White JL, Backenson BP, Dupuis AP II, Escuyer KL, et al. Potential role of deer tick virus in Powassan encephalitis cases in Lyme disease-endemic areas of New York, U.S.A. Emerg Infect Dis. 2013;19:1926–33. 10.3201/eid1912.130903 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 13.Krause PJ, Narasimhan S, Wormser GP, Barbour AG, Platonov AE, Brancato J, et al. ; Tick Borne Diseases Group. Borrelia miyamotoi sensu lato seroreactivity and seroprevalence in the northeastern United States. Emerg Infect Dis. 2014;20:1183–90. 10.3201/eid2007.131587 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 14.Centers for Disease Control and Prevention (CDC). Recommendations for test performance and interpretation from the second national conference on serologic diagnosis of Lyme disease. MMWR Morb Mortal Wkly Rep. 1995;44:590–1. [PubMed] [Google Scholar]
- 15.Nofchissey RA, Deardorff ER, Blevins TM, Anishchenko M, Bosco-Lauth A, Berl E, et al. Seroprevalence of Powassan virus in New England deer, 1979-2010. Am J Trop Med Hyg. 2013;88:1159–62. 10.4269/ajtmh.12-0586 [DOI] [PMC free article] [PubMed] [Google Scholar]