Establishment and range expansion of Dermacentor variabilis in the northern Maritimes of Canada: Community participatory science documents establishment of an invasive tick species

Andrea M Kirby; Ellis P Evans; Samantha J Bishop; Vett K Lloyd

doi:10.1371/journal.pone.0292703

. 2023 Oct 13;18(10):e0292703. doi: 10.1371/journal.pone.0292703

Establishment and range expansion of Dermacentor variabilis in the northern Maritimes of Canada: Community participatory science documents establishment of an invasive tick species

Andrea M Kirby ¹, Ellis P Evans ¹, Samantha J Bishop ¹, Vett K Lloyd ^1,^*

Editor: Brian Stevenson²

PMCID: PMC10575507 PMID: 37831710

Abstract

Tick populations are dependent on a complex interplay of abiotic and biotic influences, many of which are influenced by anthropic factors including climate change. Dermacentor variabilis, the wood tick or American dog tick, is a hardy tick species that feeds from a wide range of mammals and birds that can transmit pathogens of medical and agricultural importance. Significant range expansion across North America has been occurring over the past decades;this study documents northwards range expansion in the Canadian Maritime provinces. Tick recoveries from passive surveillance between 2012 and 2021 were examined to assess northward population expansion through Atlantic Canada. At the beginning of this period, D. variabilis was abundant in the most southerly province, Nova Scotia, but was not considered established in the province to the north, New Brunswick. During the 10-year span covered by this study, an increasing number of locally acquired ticks were recovered in discrete foci, suggesting small established or establishing populations in southern and coastal New Brunswick. The pattern of population establishment follows the climate-driven establishment pattern of Ixodes scapularis to some extent but there is also evidence of successful seeding of disjunct populations in areas identified as sub-optimal for tick populations. Dogs were the most common host from which these ticks were recovered, which raises the possibility of human activity, via movement of companion animals, having a significant role in establishing new populations of this species. Dermacentor variabilis is a vector of several pathogens of medical and agricultural importance but is not considered to be a competent vector for Borrelia burgdorferi, the etiological agent of Lyme disease; our molecular analysis of a subset of D. variabilis for both B. burgdorferi and B. miyamotoi did not confirm any with Borrelia. This study spans the initial establishment of this tick species and documents the pattern of introduction, providing a relatively unique opportunity to examine the first stages of range expansion of a tick species.

Introduction

The stability and range of animal populations are dependent on the complex interplay between biotic and abiotic factors; ticks are no exception [1–5]. Hard ticks of the family Ixodidae consist of 14 genera, including Dermacentor, of which there are approximately 40 species including several found in North America [6]. Dermacentor variabilis, colloquially referred to as the wood tick or the American dog tick, is abundant throughout much of continental USA, Mexico and southern Canada [1, 7, 8]. The range of this species has been expanding both northward into Canada and west and east across the continent [1, 7, 8]. Different tick species have an optimal combination of climactic and biological factors that influence their ability to complete their life cycle and reproduce in any given environment [1, 5, 9]. Climactic factors influencing the range of this species include rainfall, duration and magnitude of seasonal extreme temperatures, and related climactic variables. Biotic factors include land cover, host availability and host dispersal [1, 10, 11]. While ticks do not move great distances independently, they feed for several days in each life stage so infestation of a bird or large mammal can result in long-range dispersal. Dermacentor variabilis feeds from a wide range of hosts [7] so the movements of these hosts can promote wide dispersal of the tick. Human activity can affect all of the factors regulating tick distribution. Additionally, D. variabilis are among the most commonly found ticks on humans [6, 12] and are frequently found on dogs and agricultural animals so, movement of humans, companion animals or agricultural animals may significantly contribute to tick range expansion.

The large geographic range of D. variabilis and the multiple pathogens that it vectors makes this species one of the most economically and medically important tick species in North America [1]. Dermacentor variabilis is a known vector of multiple pathogens. These include Rickettsia rickettsii, the etiological agent of Rocky Mountain spotted fever [13], and more commonly, other pathogenic spotted fever-producing Rickettsia species [13] and some related Ehrlichia species such as Ehrlichia canis [14]. Additionally, D. variabilis can vector Francisella tularensis, the cause of tularemia [15, 16], other parasites including Babesisa sp. [17], known or suspected pathogenic viruses [18–20], and additionally can cause tick paralysis disease [21, 22]. D. variabilis has been found to be infected with Cytauxzoon felis, which causes serious feline disease [23, 24], Anaplasma phagocytophilum and A. marginale [25, 26], which cause human and bovine anaplasmosis, respectively, and E. chaffeensis and E. ewingii, agents of human ehrlichiosis in some [26–28], but not all [29], cases. Similarly, Borrelia burgdorferi, one of the causative agents of Lyme disease, has been identified in this and related Dermacentor species [26, 30–32]. However, for a tick to transmit rather than simply acquire a pathogen is more difficult to determine experimentally. At least for B. burgdorferi, previous research suggests that Dermacentor spp. ticks are not competent vectors of B. burgdorferi [33–37], and assumed by extension to not be competent vectors for related Borrelia species such as Borrelia miyamotoi. Nevertheless, incidences of tularemia [38], bovine anaplasmosis [39], and Rocky Mountain spotted fever [40] have worsened over recent decades in the United States. Francisella tularensis is endemic in many parts of Canada, although cases of tularemia in Canada remain rare and are thought to arise from direct exposure to the pathogen rather than the tick vector [41]. National information on the occurrences of spotted fevers and anaplasmosis is not readily available, although evidence from regional studies suggests that they may be rare but increasing [7, 8]. As D. variabilis populations expand in scope and numbers, increased encounters between humans, companion and agricultural animals will necessarily increase, making surveillance of this species of importance for both economic and human and animal health.

Nova Scotia and New Brunswick are eastern maritime Canadian provinces, with Nova Scotia lying to the south of New Brunswick. New Brunswick additionally shares a land border with the province of Quebec and the state of Maine of the USA. Relative to its neighbors, the climate of New Brunswick is cooler, with more protracted periods of snow cover and there is widespread low-elevation forested land with extensive waterways and wetlands, habitats that foster D. variabilis populations in other regions [42–46]. Dermacentor variabilis has been documented in Nova Scotia since the 1940s [42, 47]. It is reported that the tick was introduced in the early 1900s on sporting dogs from the United States [47], although population establishment by other animals or humans cannot be excluded. Since that time, the species has continued to expand its range throughout the province [42, 48]. At the start of this study, D. variabilis was abundant throughout Nova Scotia, but had not been recovered by active tick surveillance or from non-traveled hosts in New Brunswick [12, 49]. Suitable, if not optimal, climates for this tick species are present throughout much of the Canadian Maritimes, excluding northern New Brunswick, and are predicted to increase in suitability with further climate change [1, 50, 51]. Thus, it is reasonable to anticipate that D. variabilis will establish populations in New Brunswick that will subsequently expand. If distribution and expansion is driven by dispersal by wildlife hosts, the spread would likely be continuous and responsive to climate and other abiotic variables, as appears to be the case for Ixodes scapularis, a tick species that invaded the province earlier [50, 51]. In contrast, if introductions of the ticks is driven primarily by anthropic factors such as the movement of humans and companion animals the pattern of tick recoveries would be more dispersed and discontinuous, reflecting the location of introductions.

To monitor and better understand the spread of this tick species, we have analysed 10 years of tick recovery data from New Brunswick. These data were obtained from a large community science initiative in which members of the public participated in passive tick surveillance by submitting ticks found on themselves, on companion animals and in the environment, in exchange for tick identification and pathogen testing. We document the increasing local acquisition of D. variabilis from multiple discontinuous foci across the province. These foci were initially seen in the south and coastal regions with milder ambient temperatures, and later in the less temperate northern regions, suggesting population expansion is controlled both by climate and multiple independent introductions by human activity. Thus, this study spans the period of initial establishment in a region, providing a relatively unique opportunity to examine the first stages of range expansion of a tick species.

Materials and methods

Specimen acquisition

The Mount Allison Tick Bank serves as an archive of ticks and their DNA, collected through passive surveillance, primarily from New Brunswick (NB) and the other Canadian maritime provinces, Nova Scotia (NS) and Prince Edward Island (PEI). Ticks are donated by the general public, primarily via veterinary clinics but also directly from the public. When the tick bank was initiated, ticks were solicited from veterinary clinics by letter and email and presentation at the annual regional veterinary medicine conference (2012 and 2013). No organized promotion of the tick bank occurred in subsequent years although it was mentioned in sporadic media reports; engagement by veterinary clinics was fairly consistent throughout the span of the study.

Upon receipt, Ixodes spp. ticks were identified to species, life stage, sex, and state of engorgement based on [52, 53] (University of Rhode Island, www.tickencounter.org). The initial focus of the tick bank was on Ixodes species ticks, so all non-Ixodes ticks were photographed and archived; identification to species, when possible, occurred at a later date based on images and examination of archived residual specimens when possible. Each sample is accompanied by a submission form which included the date and location where the tick was encountered, instances of recent travel, whether the tick was attached, the species of the host, and contact and consent information. Photographs of the mouthparts, dorsal aspect, and ventral aspect for each tick were taken under a Leica EZ4D dissecting microscope. Ticks were subsequently longitudinally bisected (with the exception of larvae and unengorged nymphs) with half used for DNA extraction and subsequent testing and the other half archived at -20°C. This study selected those ticks which were identified as Dermacentor spp. collected in NB between 2012 and 2021. Any disclosed out-of-province travel in the two weeks prior to tick discovery was noted. These ticks were excluded from mapping (Fig 2), but not molecular analysis. Funding considerations prompted the conversion of free tick testing to a user-pay service in 2020, drastically reducing tick submissions, particularly for non-Ixodes species. An additional four tick records from 2021 were provided by a tick testing company, Geneticks [54], and 58 records of Dermacentor species with no documented travel history submitted for identification to the tick surveillance platform, eTick [48].

Fig 2 — Areas of concentration, 50km in diameter, of collection lasting > 2 years, are indicated with red circles. The GIS map template includes human health zones and scale. Map templates were obtained from ArcGIS Online maps hosted by Esri.

Mapping and statistical analysis

Mapping of the location of the tick recoveries used GIS map templates that are the intellectual property of Esri and are used herein under license (Copyright © 2020 Esri and its licensors. All rights reserved).

To assess the probability of the increased D. variabilis recoveries occurring by chance, both over time and in northern versus southern regions, chi squared analysis was used. The four years 2013–2016 (inclusive) were used as the “early” years and the four years 2017–2020 were used as “late” years. Recoveries over multiple years were combined to reduce random fluctuation in the numbers of rare recoveries. The year 2021 was excluded as submissions of all non-I. scapularis ticks decreased with the imposition of cost-recovery for tick testing; data from the year 2012 was excluded for symmetry. For geographic analysis, the province was divided into southern (health zone 1 and 2), middle (health zones 3 and 7) and northern regions (health zones 4 to 6). These regions were based on human health zones [55] rather than ecological variables as anthropic information important for passive surveillance are categorized using these health zones, but they do correspond reasonably well with geographic and climactic parameters [50].

Molecular analysis

All ticks, regardless of species and including those too damaged to identify to species, were tested upon receipt for the presence of 1–3 B. burgdorferi genes, Outer Surface Protein A (OspA), Flagellin B (FlaB) and the 23S ribosomal RNA (rRNA) gene (Table 1; [56, 57]. Presumably due to competition from tick DNA, if the abundance of the B. burgdorferi target DNA was low, in some cases not all Borrelia primers sets would produce an amplicon. This was not specific to D. variabilis as it was also noted for I. scapularis and I. cookei ticks tested in this manner [12, 58]. Extraction of DNA, amplification and visualization were completed as described by [59]. For all nested PCR (nPCR) reactions, the reaction volumes and nPCR protocol were as described in [59] with the annealing temperatures given in Table 1. Negative controls consisting of water in place of DNA were conducted at the start and end of each experimental PCR manipulation in the same workspace, in order to detect reagent contamination prior to or during nPCR or aerosolization of DNA in the PCR workspace. Tick DNA extraction, PCR manipulations and gel electrophoresis were all conducted in separate locations with independent air flow. Amplicons of sizes indicative of either Borrelia spp. or B. burgdorferi were submitted for Sanger sequencing at Génome Québec, McGill University (Montréal, QC). The resulting chromatograms were trimmed and manually curated for ambiguous nucleotides using FinchTV and a Nucleotide Blast of each sequence was performed using the National Center for Biotechnology Information’s (NCBI) GenBank.

Table 1. Primers and conditions used to amplify Borrelia DNA.

Primer	Target gene	Sequence (5’ → 3’)	Amplicon length (bp)	Melting temperature (°C)	Annealing temperature (°C)
FlaB out L	Borrelia burgdorferi FlaB	`GCATCACTTTCAGGGTCTCA`	350	62.9	55
FlaB out R		`TGGGGAACTTGATTAGCCTG`		63.9	55
FlaB in L		`CTTTAAGAGTTCATGTTGGAG`		55.6	58
FlaB in R		`TCATTGCCATTGCAGATTGT`		64.1	58
OspA out L	Borrelia burgdorferi OspA	`CTTGAAGTTTTCAAAGAAGAT`	521	54.4	55
OspA out R		`CAACTGCTGACCCCTCTAAT`		60.7	55
OspA in L		`ACAAGAGCAGACGGAACCAG`		64.4	58
OspA in R		`TTGGTGCCATTTGAGTCGTA`		64.1	58
23S out F	Borrelia spp. 23S rRNA	`GTATGTTTAGTGAGGGGGGTG`	587	57.72	50
23S out R	Borrelia spp. 23S rRNA	`GGATCATAGCTAGGTGGTTAG`	587	57.74	50
23S in F	Borrelia burgdorferi 23S rRNA	`ATGTATTCCATTGTTTTAATTACG`	340	52.22	51
23S in R	Borrelia burgdorferi 23S rRNA	`GACAAGTATTGTAGCGAGC`	340	53.66	51
23S Bmiya Fin	Borrelia miyamotoi 23S forward inner	`ATAAACCTGAGGTCGGAGG`	447		60
23S Bmiya Rin	Borrelia miyamotoi 23S reverse inner	`AAAGTGTGGCTGGATCACC`

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Results

Dermacentor recoveries

Between 2012 and 2021, 668 Dermacentor spp. ticks were collected through community-based passive surveillance in New Brunswick and submitted to the MTA Tick Lab. For 2020 and 2021, ticks and or records of 4 additional D. variablis ticks from the tick testing company, Geneticks [54] and 58 from the tick surveillance platform, eTick [48] were obtained. 141 specimens were retained after removal of submissions where the tick was acquired outside of New Brunswick, submissions that did not explicitly exclude travel outside of New Brunswick, ticks too damaged for species-level identification and D. albipictus (of which 13 were found from one moose and three dogs; Table 2).

Table 2. Summary of Dermacentor variabilis recoveries from New Brunswick by year.

	Total	Tick life stage				host
year	for year¹	adult female	adult male		larvae/nymph	dog	human	other²
2012	0	0	0		0	0	0	0
2013	7	6	1		0	6	1	0
2014	7	6	1		0	7	0	0
2015	5	4	1		0	5	0	0
2016	11	10	1		0	4	5	2
2017	15	5	10		0	10	4	1
2018	13	7	6		0	8	5	0
2019	24	12	12		0	16	6	2
2020	17	9	5		3	5	7	5
2021	42	30	12		0	7	30	5
total	141	89		49	3	68	58	15

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1. Total ticks recovered for that year. Adjacent columns provide breakdown by life stage and host.

2. Other included wildlife (deer, coyote), “walking ticks” ‐ ticks found prior to feeding, either in the outside environment, on clothes or in the house.

Dermacentor variabilis collected in New Brunswick

Of the submitted D. variabilis from New Brunswick, 98.5% (139/141) were adults. In comparison, from the neighboring province of Nova Scotia with extensive and well-established populations, 99.2% were adults (S1 Table in S1 File). Of the adult ticks, approximately 10–20% were male in the first years (2012–2016); from 2017 onwards, the proportion of males recovered increased to approximately 30–60% (Table 2). Overall, dogs were the most common host (48%), with humans also well represented (41%), although canine-derived samples were, as expected, under-represented after 2020 when free submissions were discontinued. D. variabilis were also readily found on wildlife, or walking in the outside or inside environment (Table 2), consistent with their wide host range [7]. The major peak of D. variabilis tick recoveries was from May to August (Fig 1).

There is a trend of increasing D. variabilis recoveries over time evident by inspection and supported by comparing the proportion of D. variabilis to total tick recoveries for years 2017–2020 to 2013–2016 by Chi squared analysis (p = 0.014). To determine if this might be because D. variabilis were establishing populations in the province, the geographical origins of locally acquired ticks were plotted (Fig 2). Dermacentor variabilis specimens collected in 2012 were all were associated with travel to regions with well-established and abundant D. variabilis populations (primarily Nova Scotia) [12]. Starting in 2013, locally-acquired D. variabilis were recovered in New Brunswick, although close to the New Brunswick-Nova Scotia border. This was followed in 2014 with locally-acquired ticks found in the southwest of the province in the St. John region, and by 2016, stretching along the southern portion of the province. In 2017, multiple disperse local recoveries were reported. These included recoveries from the southern and middle portions of the province and along the Maine, US border. Widely distributed and expanding populations of D. variabilis had been previously documented in Maine, including near the Maine-New Brunswick border, by 2006 [45]. By 2019, locally-acquired D. variabilis were additionally being reported along the coastal region. By 2020 D. variabilis were also recovered in the northwest of the province at the New Brunswick-Maine-Quebec border; D. variabilis having also been reported from this part of Quebec in 2017 [60]. Of note, this widespread recovery occurred during a time when non-essential travel across provincial borders was severely restricted in response to the COVID-19 pandemic. By 2021, D. variabilis, while still not abundant, was being reported throughout most of the province of New Brunswick. Chi squared analysis indicated that for both the “early expansion” period of 2013–2016 and the “later expansion” period of 2017–2020, proportion of the D. varibilis relative to total tick recoveries in the middle and northern parts of the province were greater than for the southern part of the province (p = 3.9 x e^-7 and 1.8 x e^-5, respectively), where I. scapularis was well established and a strong contributor to total tick recoveries.

Borrelia burgdorferi and B. miyamotoi in D. variabilis ticks

All ticks, regardless of species and including those too damaged to identify to species, were tested upon receipt for 1–3 B. burgdorferi genes. Twenty D. variabilis ticks showed an amplicon consistent with the potential presence of B. burgdorferi. Sequence conformation of re-amplified amplicons from the four of these ticks with at least two amplicons consistent with B. burgdorferi genes, produced only one, a D. variabilis male (S1 Fig in S1 File), obtained in 2021 from a dog from southeastern New Brunswick without a recent travel history, with a sequence consistent with the B. burgdorferi 16-23S intergenic spacer (IGS) region; sequence analysis of the B. burgdorferi Outer Surface Protein A gene segment produced uninterpretable sequence (S2 Fig in S1 File). The other three ticks produced uninterpretable sequences.

Screening of ticks for the relapsing fever spirochete, B. miyamotoi was not routinely performed upon receipt of the ticks so a total of 181 D. variabilis ticks (144 ticks collected in 2017, 34 ticks collected in 2018 and 23 from 2012–2016) were tested. In contrast to the positive control (DNA from the liver of a B. miyamotoi-infected Peromyscus leucopus) only two D. variablis ticks, both adult females from a canine host collected in 2014, produced amplicons consistent with the size expected for B. miyamotoi, however, the presence of B. miyamotoi could not be confirmed by Sanger sequencing.

Discussion

The expansion of the geographic range of tick populations, including those of D. variabilis, is being increasingly described in various parts of the world [1–4, 7]. Recovery of locally acquired D. variabilis increased in the Canadian Maritime province of New Brunswick over the 10-year span of this study; no locally acquired ticks were found when the study started in 2012 but by 2021, ticks were recorded from seven “hot spots” across the region (Fig 2; [48].

Does the presence of locally acquired ticks mean that self-sustaining populations D. variabilis have been established?

The presence of ticks could be explained by adventitious ticks translocated from adjacent high tick population areas. If these ticks were able to survive but were unable to find hosts from which to feed, find a mate or have surviving progeny, then local populations would not be able to establish. There are several lines of evidence that argue for the ticks recovered in this study representing newly established populations. The most obvious argument is that the number of tick recoveries increased throughout the time span captured in this study; populations of D. variabilis were both high and stable in the adjacent region of northern Nova Scotia since at least 2014 [12], so if the ticks recovered in New Brunswick were purely adventitious ticks, their number should have also remained stable. Additional evidence that D. variabilis recoveries represent the newly established populations include that the ticks were recovered from wildlife hosts and the recovery of immature stages in at least one year. Furthermore, D. variabilis were still recovered from multiple locations throughout the province in 2020 when provincial borders were closed to non-essential travel, and these locations were the same regions from which ticks were recovered in previous and subsequent years. The recovery of increased numbers of ticks and recoveries from dispersed locations are all consistent with the establishment of new populations, as well as with the biology of the species. With a broad host range [7] finding hosts should not be a challenge. Finding a mate is a problem that is alleviated one generation after an adult female is translocated while feeding on a host, as long as her eggs are able to hatch and the progeny thrive. As this species is a hardy one with relatively few climactic barriers [61, 62], propagation should not be a limiting consideration. To determine if the D. variabilis recoveries reported here do represent newly established populations, it would be helpful to recover additional immature developmental stages, ideally on wildlife, through active surveillance. As [63] did not recover D. variabilis specimens during active surveillance in the region during the initial time span covered by this study, 2014, repeated active surveillance would provide valuable conformation. [7] report a good correlation between active and passive surveillance in detecting northward population spread for D. variabilis and [8] document population expansion of D. variabilis in central Canada using passive surveillance, so the increasing tick recoveries in New Brunswick, reported here is likely to represent the establishment of new D. variabilis populations.

Recoveries of D. variabilis occurred from multiple locations within the province, initially in the southeast and southwest. By 2014 recoveries started to occur between these foci and in the north of the province. The pattern of D. variabilis recoveries, in the milder south and coastal regions where I. scapularis first established [50], is suggestive of establishing, and possibly established, populations in the more climactically moderate regions. However, the locally acquired D. variabilis did not all originate from the more climactically moderate regions of the province, unlike what was found for I. scapularis [50]. Climate modelling by [1] predicts the northward expansion of suitable conditions for D. variabilis populations under all climate change scenarios; these suitable regions encompass both Nova Scotia and New Brunswick. Nevertheless, their climate model indicates that both provinces are only marginally suitable for D. variabilis populations. This prediction is seemingly at odds with the abundant recoveries of D. variabilis in Nova Scotia [12, 48] coupled to the growing recoveries of D. variabilis in New Brunswick documented here. However, the model used captured climactic variables but not biotic factors such as host movement that can lead to tick introductions. Additionally, the sensitivity of such models is greater for predicting where tick populations would not be sustainable than where populations would be sustainable, neither does the model predict tick abundance [1]. D. variabilis is a tough and versatile tick, capable of survival even in ecosystems not thought to be suitable such as the challenging climate of northern Canadian Prairies [7, 61, 62] so climactic conditions may not constrain population establishment as significantly as for other tick species.

How are D. variabilis populations being established?

Inspection of the locations of locally-acquired D. variabilis in New Brunswick shows that the ticks are found in distinct and discontinuous foci, in this study, generally separated by 100 ‐ 200 km. This finding is consistent with the presence of disjunct populations in both Canada [42, 46, 47] and in the United States. These disjunct populations have been assumed to represent separate tick introductions via infested livestock or companion animals [42, 46, 47]. Perhaps not surprisingly given the common name of “American dog tick”, adult D. variabilis ticks are the predominant Dermacentor species found on companion animals in the United States [64] and specimens collected in our tick bank were frequently recovered from dogs (Table 2, [12]. Immature D. variabilis have been found feeding from small mammals [65–67] but rarely from birds or humans [68–71]. This would limit the ability of this species to disperse large distances as juveniles. Adult D. variabilis, however, readily feed from larger mammals including humans, companion and agricultural animals. This raises the obvious possibility that the distributed pattern of D. variabilis recoveries represent anthropic introductions mediated by the travel of companion dogs, a mode of introduction that has been previously implicated in the introduction of D. variabilis in other regions [42, 46, 47]. If population establishment and expansion of D. variabilis is more reflective of chance anthropic “seedings” by human actions than large scale climactic factors, risk modeling will be complex. Finer scale population surveillance that captures anthropic variables, biotic and abiotic factors that include human use of habitats, microclimates, quantification of tick density and surveillance of wildlife for the pathogens transmitted by D. variabilis, among other factors, is warranted to monitor and predict tick populations to protect human and animal health in regions of expanding tick populations.

Dermacentor variabilis and Borrelia

While D. variabilis can transmit multiple pathogens of human and veterinary importance, their ability to maintain and transmit Borrelia spirochetes remains contentious with conflicting reports. The possibility of D. variabilis ticks acquiring Borrelia spirochetes from infected hosts is not surprising, and does not necessarily mean that the ticks could transmit the pathogen. There have been studies that have detected Borrelia spirochetes in D. variabilis that fed from infected hosts. D. variabilis larvae removed from infected P. leucopus in a highly endemic area had B. burgdorferi spirochetes identified both serologically and morphologically [30]. Similarly, [32] found B. burgdorferi in adult D. reticulatus in Belarus; B. burgdorferi, B. afzelii, or B. valaisiana were identified in 2.7% of the 226 ticks tested. There also have been isolated reports of Dermacentor spp. ticks being infected with B. burgdorferi elsewhere in North America. An adult D. albipictus found feeding on a canine host in Ontario, Canada had molecularly identified B. burgdorferi, although unfortunately the dog was not tested for B. burgdorferi exposure to investigate prior infection or transmission [31]. The finding of a potentially Borrelia-positive reported D. variabilis may fall into this category of a Dermacentor tick acquiring B. burgdorferi from an infected dog, although again the dog was not tested for Borrelia. While there is evidence of D. variabilis carrying B. burgdorferi, caution needs to be exercised in interpreting these results. In all cases, amplicons suggestive of B. burgdorferi require sequence validation to confirm the presence of B. burgdorferi. By convention, amplification and sequence conformation of two or more Borrelia genes is considered necessary to consider a tick a “true” positive [12, 56], so the D. variabilis identified here would not be considered to be a true positive. This assessment criteria is designed to reduce false positives, although it can also produce false negative results. Competition from the more abundant tick DNA can reduce detection of Borrelia sequences and target DNA in archived samples is subject to DNA degradation. Conversely, PCR, the method used in most recent studies to assess the presence of Borrelia, can detect DNA from both viable and non-viable, but not yet eliminated, Borrelia leading to false positive results. [57] report that B. burgdorferi and B. miymotoi were detected in approximately 4% and 2%, respectively, of wildlife species from southern New Brunswick. If D. variabilis were efficient at acquiring and retaining Borrelia infection, approximately 6 and 4, respectively, of the ticks tested in this study would have been expected to be carrying these Borrelia species. That fewer were recovered may represent degradation of Borrelia DNA in vivo in D. variabilis ticks; assessing ticks collected by active surveillance, so possibly sooner after feeding, would address this question.

While Borrelia has been detected in D. variabilis, this does not necessarily indicate that these ticks can transmit the pathogens and previous research suggests that Dermacentor spp. ticks are not competent vectors of Borrelia burgdorferi. Their poor vectoral capacity is thought to result from the action of antimicrobial peptides and lysozymes in the tick’s haemolymph that are effective in eliminating B. burgdorferi [72, 73]. The effectiveness of this immune response was demonstrated in experiments in which B. burgdorferi was injected directly into the haemolymph of D. variabilis, causing a rapid surge in antimicrobial peptides, lysozymes, and haemocytes leading to rapid bacterial elimination [33, 34]. Consistent with this finding, D. variabilis nymphs were found to lack detectable B. burgdorferi despite molting from infected larvae and these nymphs were unable to transmit B. burgdorferi to naïve mice in the laboratory [37]. These findings are mirrored by evidence that Dermacentor ticks appear unable to maintain a B. burgdorferi infection in nature [35, 36]. Both I. scapularis and D. variabilis larvae and nymphs were found to frequently feed on white-footed mice (Peromyscus leucopus), some of which were infected with B. burgdorferi but in contrast to I. scapularis, in which multiple life stages became infected, none of the D. variabilis ticks collected from the same population of mice were found infected with B. burgdorferi [35]. Thus, as a result of this rapid clearance of B. burgdorferi, Dermacentor fails to maintain a B. burgdorferi infection long enough for the bacteria to be transferred between developmental stages and this would be expected to prevent transmission to new hosts.

Nevertheless, some case studies provide indirect evidence that Dermacentor spp. ticks may be able to vector, as well as acquire, Borrelia infections. A case study from Bulgaria described an individual bitten by a Dermacentor marginatus tick, who subsequently developed an erythema migrans (EM) rash and was then found to be positive for B. burgdorferi exposure on serology, which was confirmed positive through a skin biopsy [74]. Similar anecdotal evidence of rashes and ulcers associated with Dermacentor spp. tick bites in France has also been noted [75]. Although these studies were on Dermacentor species other than D. variabilis, these results show that Borrelia can be detected in Dermacentor genus ticks and possibly vectored by them, which has reinvigorated investigation of the vectorial potential of D. variabilis. In a large study, 127 D. variabilis were obtained from the Human Tick Test Kit Program, created for ticks removed from military personnel in Wisconsin, USA. Of those ticks, 11% tested positive for B. burgdorferi by PCR [76]. These ticks were all engorged adults removed from human hosts, implying either that the D. variabilis ticks were infected with B. burgdorferi as nymphs and retained the infection into the adult stage or that the human hosts were infected prior to the tick bite and had a high enough spirochetal load to transmit the infection to the tick. This alternative was deemed unlikely as none had a known history of Lyme disease symptoms [76]. Although D. variabilis transiently acquiring Borrelia from an infected host does not equate to ready transmission of infection, there is a possibility, if not high probability of transmission if the ticks refeed rapidly. Unambiguous evidence of the duration of viable B. burgdorferi persisting in Dermacentor spp. ticks would require culture of bacteria, collected at sequential intervals from the initial acquisition of infection. The persisting ambiguity about the ability of D. variabilis to acquire Borrelia spp. motivated our testing for B. burgdorferi and B. miyamotoi in D. variabilis ticks collected in New Brunswick. While no ticks met the formal criteria for B. burgdorferi or B. miyamotoi presence and both pathogens were under-represented in D. variabilis ticks relative to wild animals suggesting poor retention of Borrelia spp. these ticks are vectors for a variety of other pathogens that warrant surveillance and appear to be extending their range northward into New Brunswick.

Study limitations and mitigations

This study took advantage of the power of community science; the public collected and submitted ticks throughout the region in exchange for identification of the tick and pathogen testing. Despite the many advantages of this community-based passive surveillance approach, interpretation of these findings entails awareness of issues intrinsic to passive surveillance. Passive surveillance relies on public detection and submissions of ticks, but the human population is not evenly distributed. As the tick recoveries documented here were not clustered around cities (Fig 2), using the location of tick encounters rather than donor address mitigated this bias. Motivation of members of public to participate and sample damage in the mail are difficult to quantify but are highly unlikely to be uniform, however, tick donations were primarily from veterinary clinics and participating veterinary clinics were largely constant during most of the ten-year span of this study. The first foci detected was in the southeast of the province, close to the study location so it is difficult to differentiate between the proximity to Nova Scotia’s abundant D. variabilis populations from recovery bias in explaining this tick “hot spot”. Nevertheless, the southwestern foci, which was not close to the study site, appeared only a year later, nor would recovery bias apply to the eTick platform. A bias affecting host data did occur in 2020. Prior to 2020, ticks from all hosts were collected and tested, whereas financial considerations resulted in paid testing in 2020 so that after this date, submissions were human-biased. As the eTick platform does not provide tick testing and involves no cost to the image contributors, this consideration would not apply to that data set.

Conclusion

Dermacentor variabilis, the wood tick or American dog tick, is expanding its range across North America. This tick species is hardy, able to utilize diverse hosts and transmit pathogens of medical and agricultural importance. The 10-year span covered by this study documents the likely establishment of new population foci as the species expands northward. The pattern of population establishment appears responsive to both climactic factors and more random, but successful, “seeding” of populations in areas climactically sub-optimal for tick populations. As dogs were the most common host from which these ticks were recovered, human activity, via movement of companion animals, is strongly implicated as a direct driver of tick range expansion. This study spans the period during which this tick species appears to have colonized a new range and provides the opportunity to examine the dynamics of population and range expansion of an invasive tick species of medical and economic concern.

Supporting information

S1 File. Contains supporting table and figures.

(PDF)

Click here for additional data file.^{(3MB, pdf)}

S1 Raw images

(PDF)

Click here for additional data file.^{(286.9KB, pdf)}

Acknowledgments

The authors would like to thank veterinary clinics and members of the public throughout the Maritimes who contributed specimens. We thank eTick for supplying data and Anne Berthold for comments on the manuscript.

Data Availability

All tick mapping data is available at https://gnb.socrata.com/Health-and-Wellness/Tick-Data-2012-to-2018-Donn-es-relatives-aux-tique/3mpw-72pb

Funding Statement

Seed funding for the tick bank was provided by the Canadian Lyme Disease Foundation to VKL (CanLyme 2014-1, https://canlyme.com/). Operational funding was provided by the Natural Sciences and Engineering Research Council to VKL (NSERC 4426-2015, https://www.nserc-crsng.gc.ca) as well as private donations for tick research. EPE was supported by a Undergraduate Student Research Award from the Natural Sciences and Engineering Research Council (NSERC USRA). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

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PLoS One. doi: 10.1371/journal.pone.0292703.r001

Decision Letter 0

Brian Stevenson

26 Jul 2023

PONE-D-23-15954Establishment and range expansion of Dermacentor variabilis in the northern Maritimes of Canada: community participatory science documents establishment of an invasive tick speciesPLOS ONE

Dear Dr. Lloyd,

Thank you for submitting your manuscript to PLOS ONE. After careful consideration, we feel that it has merit but does not fully meet PLOS ONE’s publication criteria as it currently stands. Therefore, we invite you to submit a revised version of the manuscript that addresses all of the points raised during the review process. I concur with the reviewers that the section on screening for Borrelia burgdorferi and B. myamotoii is not necessary, and is actually distracting from the rest of the work. The manuscript describes that initial screening potentially identified B. burgdorferi, but sequencing of those amplicons showed them to not be B. burgdorferi. The one likely positive was unidentifiable, and its description suggests that it was not actually a Dermacentor. The data indicate that there was no evidence of B. miyamotoii in any of the studied ticks. As written, readers will get the impression that those spirochetes were identified in your ticks: for both bacteria, the manuscript essentially says, "we thought that we had evidence of their presence, but it turned out that we were wrong". I strongly recommend that either the section on Borrelia be omitted, or the results be described in a straightforward manner. For example, "Ticks were screened by PCR and amplicon sequencing, but no evidence was found that any Dermacentor were infected with either spirochete."

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“The authors would like to thank veterinary clinics and members of the public throughout the Maritimes who contributed specimens. We thank eTick for supplying data and Anne Berthold for comments on the manuscript.

Seed funding for the tick bank was provided by the Canadian Lyme Disease Foundation, and operational funding was provided by the Natural Sciences and Engineering Research Council as well as private donations for tick research.”

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“Seed funding for the tick bank was provided by the Canadian Lyme Disease Foundation to VKL (CanLyme 2014-1, https://canlyme.com/). Operational funding was provided by the Natural Sciences and Engineering Research Council to VKL (NSERC 4426-2015, https://www.nserc-crsng.gc.ca) as well as private donations for tick research. EPE was supported by a Undergraduate Student Research Award from the Natural Sciences and Engineering Research Council (NSERC USRA). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.”

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Reviewers' comments:

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Comments to the Author

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The manuscript must describe a technically sound piece of scientific research with data that supports the conclusions. Experiments must have been conducted rigorously, with appropriate controls, replication, and sample sizes. The conclusions must be drawn appropriately based on the data presented.

Reviewer #1: No

Reviewer #2: Yes

Reviewer #3: Yes

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2. Has the statistical analysis been performed appropriately and rigorously?

Reviewer #1: No

Reviewer #2: Yes

Reviewer #3: N/A

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The PLOS Data policy requires authors to make all data underlying the findings described in their manuscript fully available without restriction, with rare exception (please refer to the Data Availability Statement in the manuscript PDF file). The data should be provided as part of the manuscript or its supporting information, or deposited to a public repository. For example, in addition to summary statistics, the data points behind means, medians and variance measures should be available. If there are restrictions on publicly sharing data—e.g. participant privacy or use of data from a third party—those must be specified.

Reviewer #1: Yes

Reviewer #2: Yes

Reviewer #3: Yes

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Reviewer #1: Yes

Reviewer #2: Yes

Reviewer #3: Yes

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5. Review Comments to the Author

Please use the space provided to explain your answers to the questions above. You may also include additional comments for the author, including concerns about dual publication, research ethics, or publication ethics. (Please upload your review as an attachment if it exceeds 20,000 characters)

Reviewer #1: This may be a worthwhile study but requires some work before being acceptable for publication in my view.

The main issue is the simplistic treatment of the changes in numbers and geographic sources of ticks submitted in passive surveillance. Spatio-temporal changes in the proportions/populations of the public participating in passive surveillance need to be ruled out as an alternative explanation. This may be possible if the IDs of individual submitters is known, and an alternative is to ‘calibrate’ passive surveillance data against field surveillance data.

Introduction

In the introduction it is mentioned that D. variabilis is a vector of Anaplasma phagocytophilum (main vector I. scapularis and I. pacificus) and Ehrlichia chaffeensis (main vector A. americanum). There may be articles on vector competence of D. variabilis for these bacteria that I’m not aware of – if so they should be cited. However, I think, as for B. burgdorferi detections in these ticks, there are simply some articles that have found DNA in small numbers of the ticks, which may represent a past blood meal on a host infected with the bacteria rather than being evidence of vector competence (e.g. https://academic.oup.com/jme/article/40/4/534/999470). Therefore, it should be mentioned that while these bacteria have been found in D. variabilis, vector competency studies are needed to assess their role in transmission cycles, and their risk to human health. Similarly references should be provided for statements about vector competency for other pathogens cited.

When using scientific names to start a sentence, spell out the genus. Please use “these data” rather than “this data”.

The following section needs rewriting. “Suitable, if not optimal, climates for this tick species are present throughout the Canadian Maritimes and are predicted to increase in suitability with further climate change (Boorgula et al., 2020). Thus, it can be anticipated that D. variabilis will establish populations in New Brunswick which will subsequently expand. If the spread is limited by climate, the pattern of establishment will mimic that of Ixodes scapularis, a tick species that invaded the province earlier (Lieske & Lloyd, 2018; McPherson et al., 2017). In contrast, if the province is already suitable in climate, D. variabilis expansion into the region would be instead limited by introductions of the ticks.”

Boorgula et al. (2020) suggested that only southern New Brunswick was climatically suitable for D. variabilis. It is unlikely that climate change-driven range expansion of D. variabilis will precisely mimic that of I. scapularis as these ticks likely have rather different climatic thresholds for survival of their populations.

Methods

There is no mention of the keys or at least criteria used to identify the ticks to species and this needs to be mentioned.

As the PCR methodology has been previously published, and presuming that the method used was as published, I don’t think details of the primers (Table 1) and PCR cycle conditions are needed.

Results

That additional ticks were obtained from Geneticks and eTick needs to be mentioned in the methods rather than in results.

The demonstration of range expansion depends on by-eye examination of maps in figure 2. These maps are very small and difficult to view. The range expansion (by eye) is approximately 350km in 8 years, which would seem rapid. Apart from year-on-year increases in the numbers of ticks submitted (shown in figure 1), there is no form of statistical analysis or formal quantification of changes in geographic patterns and numbers of ticks. There is a need to rule out other possible causes of the apparent range expansion, which is that there is an increased participation by the public, over a wider are of New Brunswick, during the period of the study. At present it is an assumption that public participation was constant throughout the study.

The results of PCR testing are confusing. It is not clear why some ticks would test positive for Fla B and not Osp A, while for others the inverse was seen. Only 5 of 27 ticks tested for 16-23 IGS were positive. If B. burgdorferi were present in a tick surely all would be positive. I don’t see why results from H. leporispelustris ticks would be included here.

Discussion

The argument that abundant recovery of male ticks by 2017 supports existence of established populations, on the basis that “male ticks do not feed for long and so are less likely to be adventitious” is likely incorrect. Male and female adult ticks, if adventitious, would have most likely been dispersed as nymphal ticks.

The section on possible transmission of B. burgdorferi by D. variabilis is speculative and not helpful to the articles.

Reviewer #2: The manuscript by Kirby et al., present data on Establishment and range expansion of Dermacentor variabilis in the northern Maritimes of Canada. Overall, the manuscript is well described, and the information is interesting and important for researchers in the field of tick-borne diseases and ticks.

Only minor revisions are suggested to improve the manuscript.

The authors mentioned they conducted PCR to screen Dermacentor ticks for both B. burgdorferi and B. miyamotoi without doing a PCR to confirm and check tick DNA integrity. Please clarify? Also clarify if the tick is positive for Borrelia spp why some genes are positive, and some genes didn’t work with PCR?

Reviewer #3: I enjoyed this descriptive paper that focused on the ability for passive sampling and community science to document detection and range expansion of an invasive species. It is clear, and well-written. It also sheds light on a perceived ‘second rate’ tick species that receives much less attention than the blacklegged tick, but due to its potential medical importance, should be routinely monitored.

I mainly have minor comments that address typographical errors in the document.

Keywords: variabilis is misspelled

Last paragraph before the Materials and Methods: There is a sentence beginning with “This data” which likely should be “These data”

Under “Molecular Analysis” – there is an extra parenthesis before Libernardo

Table 2 – bold table title, and write genus name and province in full. I’d also recommend centering the column headers.

Some readers may be interested in how many D. albipictus you had in your submissions – do they account for a significant amount?

No description in methods of how you generated the maps in Fig 2 – I’d suggest including this.

The format of your subheadings changes between methods and results – pick one?

Figure 1 – this is minor, but there’s enough room on the x axis to write out the full names of the months; would that be possible to do? Also, it’s almost impossible to tell the difference between some of the more closely-shaded greys, making it hard to tell if the bars in March and April are from 2015, 2016, or 2017. Is it possible to add a hashing pattern or something to help distinguish? I’d also suggest that the figure caption should include some additional information on how the ticks were collected (e.g. passive submission).

In the results, one of my main points of consideration was that the increases over time could be related to increasing awareness of your tick services (which could also be correlated with the geographic spread of information away from the location of your tick centre). However, I think that you addressed this as a possible limitation, while also demonstrating that these are likely established populations. Thus, regardless of whether you do have a degree of sampling bias, it seems likely that your results overall demonstrate a new, and likely increasing, population of D. variabilis in NB.

Figure 2- the maps are a bit small; if the lines on the maps are differentiating the health zones, it is impossible to tell – is there any chance of increasing the size of the maps slightly and perhaps arranging them with 3 across? That would orphan one, but might help the size issue. Or, alternatively, if the health zones are important could you add numbers that can be seen more clearly? Finally, could you cite where these health zone designations come from?

On the next page after Fig 2 – I don’t think the genus for leporispalustris was given previously – write in full, if not.

Missing parenthesis after Peromyscus leucopus near bottom of a page in the discussion (no page #s!)

Suggest including a reference for “male ticks do not feed for long…”

Grubhoffe and Hynes references are italicized

Something a bit grammatically strange in the sentence “An adult D. albipictus was found…” – read through again? Perhaps remove the “was”?

Suggest starting a new paragraphs at “While there is evidence of D. variabilis carrying…”

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Reviewer #1: No

Reviewer #2: No

Reviewer #3: No

**********

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PLoS One. 2023 Oct 13;18(10):e0292703. doi: 10.1371/journal.pone.0292703.r002

Author response to Decision Letter 0

9 Sep 2023

Dear Dr. Stevenston,

Thank you for your managing our manuscript “Establishment and range expansion of Dermacentor variabilis in the northern Maritimes of Canada: community participatory science documents establishment of an invasive tick species”. We are delighted that the data on the range expansion of D. variabilis was felt to be of value to the research community. We would like to thank you and all the Reviewers for your and their time in reading the manuscript and providing such insightful comments. It is a rare to get such penetrating and constructive comments and we feel the manuscript is very much improved as a result.

We have made all the corrections and changes requested, with the exception of not completely deleting but merely greatly shortening the section on Borrelia spp. in D. variabilis (rationale for this decision is detailed below). The clean revised and track-changed version of the manuscripts have been uploaded with this submission, along with the supplemental material and original gel images.

A detailed explanation and tracking of responses are provided below. The most significant changes are:

• For the issue of whether there Borrelia spp. are found in D. variabilis ticks, I would prefer to retain that information - it is an important question from a public health perspective and common question from the public as adult D. variabilis readily feed on humans. This was the original motivation for addressing this question. This work also represented a year's worth of work for each of the first two student authors. And although negative data doesn’t make for exciting reading, it is still of value and B. miyamotoi remains understudied. However, I completely agree that the previous narrative style was an unnecessarily diffuse and confusing way to present the information. To address this problem, I have greatly shortened this section. I have also firmly placed it within the context of the difference between a tick acquiring a pathogen and a tick being able to vector the pathogen. As this section is now more concise, and, I believe, clearer and addresses a point of public health importance, albeit with negative data, I would argue that its inclusion remains of value.

• The distinction between a tick being able to acquire a pathogen, Borrelia spp. or others, and being able to transmit it is now made much more explicitly and reiterated in the introduction, results and discussion.

• The question of whether increased recoveries of D. variabilis represent increased presence or increased search effort is now addressed much more explicitly in the MM, Results and Discussion. Statistical analysis, albeit simple statistical analysis due to the nature of the data, is now presented in the Results to address the question of range expansion versus increased surveillance effort.

• We have reformatted the maps to make them easier to view, as suggested by both reviewers. While the current format was the one suggested by Reviewer 3, the format that allows for the largest individual panels is a landscape orientation. This variation is also in the submitted material, should it be useful.

• We have rewritten the portion of the introduction and discussion that addresses the driver(s) of tick range expansion to emphasize the hypothesized anthropic aspect proposed here.

• We have clarified the PCR methodology, both details and limitations, in the MM, Results and Discussion.

We have addressed the comments of the Reviewers and details of these changes are provided below, and in the track-changed manuscript. Again, we express our appreciation for the time and effort taken both by the Editor and the Reviewers in reviewing the manuscript. We always appreciate the time and suggestions of Reviewers but these reviews were exceptionally penetrating and thoughtful and we feel that addressing them has made for a stronger work.

The reviewer comments are in italics and our responses are inter-digitated below each. Line numbers refer to the track-changed version of the manuscript.

Again with our thanks,

Vett Lloyd (for all authors)

Detailed responses to Editorial notes and Reviewers

Editorial Issues:

1. I believe that the manuscript is now formatted correctly, or at least more correctly.

2. Acknowledgments: We have removed the funding acknowledgements from the “Acknowledgements”. I had left them there because I was initially unable to enter the Canadian Lyme disease Foundation (CanLyme) in the funding section drop down menu, however, the funding statement is correct and we have removed the duplicate information from the acknowledgements.

3. “Data not shown” item: This phrase was removed – in retrospect, its inclusion was not helpful – there were no sequences, so nothing was available to show. The statement “the presence of B. miyamotoi could not be confirmed by Sanger sequencing” conveys that information much more appropriately.

4. Use of GIS template maps. We have looked into the copyright issue for the map templates we used and have confirmed that academic use of these templates is permitted. The information page ( - https://doc.arcgis.com/en/arcgis-online/reference/display-copyrights.htm) states the following:

The following uses are permitted:

• Personal use, internal business use, or to include in a presentation or a report for a client

• In brochures and marketing collateral, or on a company website to promote your own products and services and display your store locations

• In academic publications (for example, research journals, textbooks, and so on)

• In government works, so long as the government agency clearly delineates between government works that are in the public domain and third party works that are protected by copyright. The following attribution is recommended as a caption to the image: Map image is the intellectual property of Esri and is used herein under license. Copyright © 2020 Esri and its licensors. All rights reserved.

We have amended the image captions and the MM to include this information – and I apologize for not researching this prior to submission. I had assumed that use of the templates were permitted, but hadn’t researched it sufficiently to be certain at the time of submission, which is why I indicated that there might be copyright issues. I have now confirmed that there are no copyright issues, to the best of my ability to determine.

5. Original images of the gels in the supplemental material are provided.

6. The supporting information has been removed from the main manuscript and is now a separate file.

Reviewer: 1

General comment:

The main issue is the simplistic treatment of the changes in numbers and geographic sources of ticks submitted in passive surveillance.

Apart from year-on-year increases in the numbers of ticks submitted (shown in figure 1), there is no form of statistical analysis or formal quantification of changes in geographic patterns and numbers of ticks. There is a need to rule out other possible causes of the apparent range expansion, which is that there is an increased participation by the public, over a wider are of New Brunswick, during the period of the study. At present it is an assumption that public participation was constant throughout the study.

The demonstration of range expansion depends on by-eye examination of maps in figure 2. These maps are very small and difficult to view.

This is an important issue which we had addressed only in passing in the discussion (limitations and mitigations). We have now addressed this question more explicitly in the Results section (with concomitant details in the MM).

Spatio-temporal changes in the proportions/populations of the public participating in passive surveillance need to be ruled out as an alternative explanation. This may be possible if the IDs of individual submitters is known, and an alternative is to ‘calibrate’ passive surveillance data against field surveillance data.:

Search effort: It is difficult to rule out increased recoveries based on knowing the IDs of participants; the ticks were submitted by NB veterinary clinics and while we do have records of the names of tick donors, this is not particularly meaningful. That said, outreach to veterinary clinics occurred in 2012 and 2013 (by letter/email and presentation at the provincial veterinary medicine conference) when the tick bank initiative was started. There was no organized recruitment of clinics after that point (ie we responded to calls from vet clinics asking about tick testing but we did not approach any clinics). Clinic engagement remained constant through the duration of the study with the exception of loss of clinics starting in ∼ 2017/2018 when private clinics were bought out by a veterinary medicine consortium; the consortium did not appear to support free services so submissions from some clinics were lost. This change would have resulted in under-reporting of tick recoveries, however, rather than over-reporting.

Action: A briefer version of the recruitment strategy has now been added to the MM and this elaboration on the point of search effort has been added to the section “study limitations and mitigations” in the discussion (Lines 169-175 and 592-594).

Calibration against active surveillance: Active surveillance for D. variabilis would be the ideal calibration. Unfortunately, I’m not award of past active surveillance that detected D. variabilis in this region and initiating active surveillance would be beyond the scope of this study, although the value of doing so is noted (Line 414). Gabriele-Rivet et al (https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0131282) did conduct active surveillance in the province in 2014 and did not detect any D. variabilis. This isn’t overly surprising as during this year only ∼ 1% of ticks recovered by passive surveillance were D. variabilis.

Action: This is a valuable point to explicitly note, and we have done so (Lines 414-417).

Statistical analysis of range expansion: Providing a quantitative correlate to the visual presentation of the range expansion data we did a simple statistical analysis of the data to demonstrate that that numbers of D. variabilis recovered increased over time and also was over-represented from the north and middle of the province (due to the dearth of I. scapularis recoveries from these regions – the absolute numbers of D. variabilis recovered from the southern regions was greater than in the middle of the north of the province.

Action: Explanation on the application of the Chi squared testing is provided in the MM (Lines 202-213) and results are now mentioned in the Results section (Lines 293-295 and 313-318). The size and presentation of the maps have been improved.

Thank you very much for these comments. We had elided a description of known and suspected pathogens. With reorganization and clarification of this paragraph, the presentation of this information is much clearer.

Action: This paragraph has been reorganized to a) provide full primary citations b) separate the pathogens for which vector competence has been confirmed from those where the pathogens may simply have been acquired from infected hosts and c) explicitly point out this distinction and the need for experimental confirmation of vector competence (Lines 87-121).

Thank you again for this excellent comment. This paragraph very much needed rewriting for clarity. The original intention of this paragraph was to set up a (simplistic) set of hypotheses for the source of D. variabilis range expansion – natural vs anthropic forces, although the biology is always more complicated, as noted. This intent was compromised by less than clear writing.

Action: This paragraph has been rewritten and broken into two paragraphs to clarify the attempt to distinguish between anthropic and natural drivers of introduction and range expansion (Lines137-163). The reference to the climactic suitability has been amended (Line 138)– thank you. The comparison between I. scapularis and D. variabilis range expansion has been clarified – the point was the role of climatic abiotic forces rather than expecting the two tick species to follow the same pattern of expansion. This, however, was not what was stated in the original version. Thank you again for flagging this.

As the PCR methodology has been previously published, and presuming that the method used was as published, I don’t think details of the primers (Table 1) and PCR cycle conditions are needed.

The details of PCR cycles have been deleted (Lines 239-249). Some of the primers used, but not all, are described in the given citation so we retained Table 1, which lists all primers used.

This point was also flagged by Reviewers 2 and 3. This is most likely a problem causes by a low number target copies relative to tick or host DNA as we see it fairly commonly in PCR of non-engorged ticks (regardless of species). Additional explanation is provided in the MM (Lines 224-228 and Discussion Lines 493-499).

The section on possible transmission of B. burgdorferi by D. variabilis is speculative and not helpful to the articles.

The value of the Borrelia testing section was also flagged by Reviewer 3 and the Editor. The observation that it is tangential to the main point of the study – D. variabilis range expansion – is entirely correct. Nevertheless, this is a question that comes up frequently as the tick species is often found feeding from human hosts, which is why we addressed it. As it represented substantial work by two of the student authors, I would prefer to retain this section, albeit in a very much more succinct form and with the distinction between sporadic acquisition of pathogen from a host vs vector capacity made very clear.

Action: This section has been greatly truncated (and the information on other tick species deleted – Lines 335 - 353). The distinction between acquisition of Borrelia spp. vs transmission is much more clearly delineated in the introduction and discussion (Lines 106-107, 509-510).

This is a good point, also flagged by Reviewer 3. While larval and nymphal D. variabilis are typically found feeding from small mammals and rarely from birds or larger mammals (ie doi: 10.1093/jmedent/33.3.379, doi: 10.1093/jmedent/32.4.453, doi: 10.1093/jmedent/30.4.740, doi: 10.1139/z79-258, doi: 10.1139/z78-004), which would limit their dispersal as immatures, the overall point of extrapolating from tick sex to the source of their acquisition was weak and peripheral, and has now been deleted (Lines 399-405).

The range expansion (by eye) is approximately 350km in 8 years, which would seem rapid.

This is a very good point and supports the proposal that the dispersal of this tick species is driven by anthropic forces – presumably quite literally. This is now noted in the discussion (Lines 446-448)

I don’t see why results from H. leporispelustris ticks would be included here.

Agreed – this is a distraction, inconclusive and is now deleted (Line 344).

Thank you

The authors mentioned they conducted PCR to screen Dermacentor ticks for both B. burgdorferi and B. miyamotoi without doing a PCR to confirm and check tick DNA integrity. Please clarify?

This was poorly phrased on our part. At the time of initial testing of the ticks, the extracted DNA was checked for integrity to confirm that the DNA extraction generated product suitable for analysis. These DNA samples were then stored at -20oC for future analysis, including re-testing of putative Borrelia-positive Dermacentor ticks. During this time some DNA samples appear to have degraded, possibly due to freezer malfunction or thawing during routine freezer cleaning. This point is now mentioned in the text (Line 496-499).

Also clarify if the tick is positive for Borrelia spp why some genes are positive, and some genes didn’t work with PCR?

This is a good point flagged by the other reviewers as well. This arises, presumably, from a sensitivity issue in picking out the target Borrelia sequence in the context of more abundant vector DNA. This point has been added to the MM and is expanded upon in the Discussion (Lines 224-228 and 493-495).

Thank you!

Some readers may be interested in how many D. albipictus you had in your submissions – do they account for a significant amount?

Few D. albipictus were recovered as the tick bank primarily receives ticks from pets and only occasionally will a hunter submit ticks from a moose or their hunting dogs. We received 13 over the 10 years of the study, but these represented 4 from 1 moose carcass in 2015 (there were presumably more that were not collected from the carcass), 7 from a single hunting dog associated with that moose hunt, and 2 others, each from different dogs in 2019. A sentence of information on D. albipictus has been added to the results section (Line 268).

Thank you for this note – distinguishing between recoveries due to increased “search effort” versus increased tick numbers, was a concern also noted by Reviewer 1. We have tried to address this point by providing more information on the recruitment strategy in the MM and further elaboration on this point in the Discussion section “study limitations and mitigations” (Lines 169-175 and 592-594). We also provide a simple statistical testing of D. variabilis population increases in the MM (Lines 202-213) and results (Lines 293-295 and 313-318).

Keywords: variabilis is misspelled

Thank you. I believe that this will need to be corrected on the manuscript submission platform, which I hope that we can do ourselves, otherwise I will reach out to the editorial office for assistance. Thank you for noting this!

Finally, could you cite where these health zone designations come from?

Thank you for these suggestions. The 3X3+1 format works quite well – I was initially concerned that the orphaned year would look strange, but it works well. I have modified both maps, Figure 2 and Supplemental Figure 3 in this way. I also found that by making a horizontal rather than vertical figure, each panel could be further expanded. I will include these as alternate formats when submitting as changing from portrait to landscape in the manuscript could be disruptive.

The increased size of the panels should make the health zones larger. They have little intrinsic meaning other than they are supposed to represent approximately equal human population groups. With the addition of analysis of population-based recovery to the manuscript, which alludes to these zones, depicting them now makes more sense. A citation for these zones is now provided (Lines 208-210).

Suggest including a reference for “male ticks do not feed for long…”

This point has been removed – as noted by Reviewer 1, the argument is not strong I had elided repletion with feeding time so the argument that recovery of male ticks could be used as an indicator of established populations became too weak to include (Lines 399-401). We thank the reviewers for raising this point!

Corrections relating to the minor comments are listed below.

Minor Comments: These have been addressed. We thank the reviewers for noting them, with some embarrassment for not having noted the typographical errors (and error of grammar in the use of “data”) ourselves. We are very grateful for the reviewers’ thoroughness in reading and reviewing the manuscript.

R1 When using scientific names to start a sentence, spell out the genus.

R1 and R3 Please use “these data” rather than “this data”.

R1 There is no mention of the keys or at least criteria used to identify the ticks to species and this needs to be mentioned (Line 177).

R1 That additional ticks were obtained from Geneticks and eTick needs to be mentioned in the methods rather than in results (Lines 192-195).

R3 Under “Molecular Analysis” – there is an extra parenthesis before Libernardo

R3 Table 2 – bold table title, and write genus name and province in full. I’d also recommend centering the column headers.

R3 No description in methods of how you generated the maps in Fig 2 – I’d suggest including this.(Added – Lines 199-201)

R3 The format of your subheadings changes between methods and results – pick one?

F3 Figure 1 – this is minor, but there’s enough room on the x axis to write out the full names of the months; would that be possible to do? Also, it’s almost impossible to tell the difference between some of the more closely-shaded greys, making it hard to tell if the bars in March and April are from 2015, 2016, or 2017. Is it possible to add a hashing pattern or something to help distinguish? I’d also suggest that the figure caption should include some additional information on how the ticks were collected (e.g. passive submission).

R3 On the next page after Fig 2 – I don’t think the genus for leporispalustris was given previously – write in full, if not. (Sorry – this is now deleted information – Line 344)

R3 Missing parenthesis after Peromyscus leucopus near bottom of a page in the discussion

R3 (no page #s!)- Sorry about that!

R3 Grubhoffe and Hynes references are italicized

R3 Something a bit grammatically strange in the sentence “An adult D. albipictus was found…” – read through again? Perhaps remove the “was”?

R3 Suggest starting a new paragraphs at “While there is evidence of D. variabilis carrying…”

Attachment

Submitted filename: Response to Reviewers - Dermacentor range expansion.docx

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PLoS One. doi: 10.1371/journal.pone.0292703.r003

Decision Letter 1

Brian Stevenson

27 Sep 2023

Establishment and range expansion of Dermacentor variabilis in the northern Maritimes of Canada: community participatory science documents establishment of an invasive tick species

PONE-D-23-15954R1

Dear Dr. Lloyd,

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Reviewers' comments:

PLoS One. doi: 10.1371/journal.pone.0292703.r004

Acceptance letter

Brian Stevenson

5 Oct 2023

PONE-D-23-15954R1

Establishment and range expansion of Dermacentor variabilis in the northern Maritimes of Canada: community participatory science documents establishment of an invasive tick species

Dear Dr. Lloyd:

I'm pleased to inform you that your manuscript has been deemed suitable for publication in PLOS ONE. Congratulations! Your manuscript is now with our production department.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

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Data Availability Statement

All tick mapping data is available at https://gnb.socrata.com/Health-and-Wellness/Tick-Data-2012-to-2018-Donn-es-relatives-aux-tique/3mpw-72pb

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PERMALINK

Establishment and range expansion of Dermacentor variabilis in the northern Maritimes of Canada: Community participatory science documents establishment of an invasive tick species

Andrea M Kirby

Ellis P Evans

Samantha J Bishop

Vett K Lloyd

Roles

Abstract

Introduction

Materials and methods

Specimen acquisition

Fig 2. The distribution of locally-acquired D. variabilis ticks from New Brunswick from 2012–2021.

Mapping and statistical analysis

Molecular analysis

Table 1. Primers and conditions used to amplify Borrelia DNA.

Results

Dermacentor recoveries

Table 2. Summary of Dermacentor variabilis recoveries from New Brunswick by year.

Dermacentor variabilis collected in New Brunswick

Fig 1. Locally-acquired Dermacentor variabilis recoveries by passive surveillance, by month, in New Brunswick from 2013 to 2020.

Borrelia burgdorferi and B. miyamotoi in D. variabilis ticks

Discussion

Does the presence of locally acquired ticks mean that self-sustaining populations D. variabilis have been established?

How are D. variabilis populations being established?

Dermacentor variabilis and Borrelia

Study limitations and mitigations

Conclusion

Supporting information

Acknowledgments

Data Availability

Funding Statement

References

Decision Letter 0

Brian Stevenson

Roles

Author response to Decision Letter 0

Decision Letter 1

Brian Stevenson

Roles

Acceptance letter

Brian Stevenson

Roles

Associated Data

Supplementary Materials

Data Availability Statement

ACTIONS

PERMALINK

RESOURCES

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