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Co-feeding transmission in Lyme disease pathogens

Published online by Cambridge University Press:  08 October 2014

MAARTEN J. VOORDOUW*
Affiliation:
Institute of Biology, Laboratory of Ecology and Evolution of Parasites, University of Neuchâtel, Emile Argand 11, 2000 Neuchâtel, Switzerland
*
* Corresponding author. Institute of Biology, Laboratory of Ecology and Evolution of Parasites, University of Neuchâtel, Emile Argand 11, 2000 Neuchâtel, Switzerland. E-mail: [email protected]
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Summary

This review examines the phenomenon of co-feeding transmission in tick-borne pathogens. This mode of transmission is critical for the epidemiology of several tick-borne viruses but its importance for Borrelia burgdorferi sensu lato, the causative agents of Lyme borreliosis, is still controversial. The molecular mechanisms and ecological factors that facilitate co-feeding transmission are therefore examined with particular emphasis on Borrelia pathogens. Comparison of climate, tick ecology and experimental infection work suggests that co-feeding transmission is more important in European than North American systems of Lyme borreliosis, which potentially explains why this topic has gained more traction in the former continent than the latter. While new theory shows that co-feeding transmission makes a modest contribution to Borrelia fitness, recent experimental work has revealed new ecological contexts where natural selection might favour co-feeding transmission. In particular, co-feeding transmission might confer a fitness advantage in the Darwinian competition among strains in mixed infections. Future studies should investigate the ecological conditions that favour the evolution of this fascinating mode of transmission in tick-borne pathogens.

Type
Review Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/3.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © Cambridge University Press 2014

INTRODUCTION

Co-feeding transmission is a mode of transmission that has been reported for a wide diversity of vector-borne pathogens (Jones et al. Reference Jones, Davies, Steele and Nuttall1987; Randolph et al. Reference Randolph, Gern and Nuttall1996; Mead et al. Reference Mead, Ramberg, Besselsen and Mare2000; Higgs et al. Reference Higgs, Schneider, Vanlandingham, Klingler and Gould2005). With respect to tick-borne pathogens, this mode of transmission was first discovered for tick-borne viruses such as Thogoto virus (Jones et al. Reference Jones, Davies, Steele and Nuttall1987) and tick-borne encephalitis virus (TBEV) (Alekseev and Chunikhin, Reference Alekseev and Chunikhin1990; Labuda et al. Reference Labuda, Kozuch, Eleckova, Williams, Nuttall, Elecková, Zuffová and Sabó1993a , Reference Labuda, Williams, Danielova, Jones and Nuttall b ) and was subsequently described in Borrelia burgdorferi sensu lato (s. l.), the complex of spirochaete bacteria that causes Lyme borreliosis (Gern and Rais, Reference Gern and Rais1996; Randolph et al. Reference Randolph, Gern and Nuttall1996). While the importance of co-feeding transmission for TBEV epidemiology is now widely accepted (Randolph, Reference Randolph2011), the role of co-feeding transmission in the epidemiology of B. burgdorferi s. l. is more controversial (Randolph et al. Reference Randolph, Gern and Nuttall1996; Richter et al. Reference Richter, Allgower and Matuschka2002, Reference Richter, Allgower and Matuschka2003; Randolph and Gern, Reference Randolph and Gern2003). The controversy of whether co-feeding transmission is ecologically relevant to Borrelia pathogens has recently been invigorated with a number of theoretical and experimental studies. Theoretical work on the basic reproductive number of tick-borne pathogens suggests that co-feeding makes a modest contribution to Borrelia fitness but that spirochaetes can invade tick populations without this mode of transmission (Hartemink et al. Reference Hartemink, Randolph, Davis and Heesterbeek2008; Harrison et al. Reference Harrison, Montgomery and Bown2011; Harrison and Bennett, Reference Harrison and Bennett2012. In contrast, the fieldwork suggests that co-feeding transmission may enhance Borrelia fitness in vertebrate hosts that are otherwise refractory to systemic infection by spirochaetes (Morán Cadenas et al. Reference Morán Cadenas, Rais, Humair, Douet, Moret and Gern2007; Kiffner et al. Reference Kiffner, Lodige, Alings, Vor and Ruhe2011; Kjelland et al. Reference Kjelland, Ytrehus, Vikoren, Stuen, Skarpaas, Vikørren and Slettan2011). Experimental infection work has found evidence for genetic variation in co-feeding transmission among strains of Borrelia suggesting that this trait can evolve in response to natural selection (Tonetti and Gern, Reference Tonetti and Gern2011). Thus co-feeding transmission could influence the Darwinian competition among strains for transmission success and by extension, the genetic community of Borrelia strains in the populations of the tick vector and the reservoir host (Pérez et al. Reference Pérez, Kneubühler, Rais, Jouda and Gern2011). In addition, co-feeding transmission may facilitate contact between Borrelia genospecies that are adapted to different vertebrate host species (Kurtenbach et al. Reference Kurtenbach, De Michelis, Sewell, Etti, Schafer, Hails, Collares-Pereira, Santos-Reis, Hanincova, Labuda, Bormane and Donaghy2001; Pichon et al. Reference Pichon, Egan, Rogers and Gray2003; Herrmann et al. Reference Herrmann, Gern and Voordouw2013). Thus co-feeding transmission may allow genetic exchange between Borrelia pathogens that are otherwise genetically isolated. In the present review, I discuss the ecological significance of co-feeding transmission and the underlying molecular mechanisms with particular emphasis on its importance to Borrelia pathogens.

CO-FEEDING TRANSMISSION AND TICK-BORNE PATHOGENS

Definition of co-feeding transmission of tick-borne pathogens

Co-feeding transmission is a mode of transmission of vector-borne pathogens that is distinct from systemic transmission (Fig. 1). Co-feeding transmission occurs when infected and uninfected vectors feed in spatiotemporal proximity to each other on the same reservoir host (Randolph et al. Reference Randolph, Gern and Nuttall1996; Randolph, Reference Randolph2011). This mode of transmission may be particularly significant for tick-borne pathogens because ticks, unlike other arthropod vectors, often attach to the host for several days to obtain a meal (Randolph, Reference Randolph1998; Nuttall, Reference Nuttall1999). Co-feeding transmission often depends on an ephemeral, localized infection in the skin and is distinct from systemic transmission where the vector-borne pathogen disperses from the initial bite site and establishes a widespread (systemic) infection in the host organism (Fig. 1). In co-feeding transmission, the host acts as a transient bridge that brings infected and uninfected ticks together in the same time and place to facilitate pathogen exchange (Randolph, Reference Randolph2011). By contrast, in systemic transmission, the infected host acts as a reservoir from which vectors can acquire the pathogen for weeks or even months after the host became infected. In systemic transmission, there is often a latency period where the pathogen is replicating inside the host but the latter is not yet infectious to new vectors. By contrast, the latency period of co-feeding transmission is much shorter and is virtually instantaneous for some tick-borne viruses.

Fig. 1. The diagram shows (A) co-feeding (nymph-to-larva) transmission and (B) systemic (host-to-larva) transmission of Borrelia spirochaetes in a rodent reservoir host. Co-feeding transmission can occur when ticks feed in close spatial and temporal proximity on the same host. Larva 2 does not acquire spirochaetes via co-feeding transmission because it is too far away from the infected nymph. Systemic transmission occurs once the spirochaetes have had enough time to disseminate to all the relevant tissues of the reservoir host, which usually takes about 2 weeks. Under systemic transmission, larvae can acquire spirochaetes by attaching anywhere on the infected mouse.

Tick-borne pathogens capable of co-feeding transmission

Co-feeding transmission was first demonstrated in two tick-borne viruses: Thogoto virus (Jones et al. Reference Jones, Davies, Steele and Nuttall1987) and TBEV (Alekseev and Chunikhin, Reference Alekseev and Chunikhin1990; Labuda et al. Reference Labuda, Kozuch, Eleckova, Williams, Nuttall, Elecková, Zuffová and Sabó1993a , Reference Labuda, Williams, Danielova, Jones and Nuttall b ). These two arboviruses were both transmitted between co-feeding ticks without inducing detectable viral titres (viraemia) in the blood of their rodent hosts (Jones et al. Reference Jones, Davies, Steele and Nuttall1987; Labuda et al. Reference Labuda, Kozuch, Eleckova, Williams, Nuttall, Elecková, Zuffová and Sabó1993a , Reference Labuda, Williams, Danielova, Jones and Nuttall b ). Labuda et al. (Reference Labuda, Kozuch, Zuffova, Eleckova, Hails and Nuttall1997) demonstrated that co-feeding transmission of TBEV can even occur on immunized rodents where sterilizing antibodies prevent the development of a viraemic infection. By knocking out systemic infection, this immunization experiment provided an elegant demonstration that co-feeding transmission is a distinct mode of pathogen transfer that can operate independently from systemic transmission (Labuda et al. Reference Labuda, Kozuch, Zuffova, Eleckova, Hails and Nuttall1997). Following its discovery in tick-borne viruses, co-feeding transmission was subsequently demonstrated in two groups of tick-borne bacteria: intracellular gram-negative bacteria belonging to the genus Anaplasma (formerly Ehrlichia) (Levin and Fish, Reference Levin and Fish2000) and spirochaete bacteria belonging to the B. burgdorferi s. l. genospecies complex (Gern and Rais, Reference Gern and Rais1996; Patrican, Reference Patrican1997; Sato and Nakao, Reference Sato and Nakao1997; Piesman and Happ, Reference Piesman and Happ2001; Richter et al. Reference Richter, Allgower and Matuschka2002; Hu et al. Reference Hu, Cheminade, Perret, Weynants, Lobet and Gern2003). Interestingly, the Anaplasma genus exhibits species-specific differences in co-feeding transmission as the phenomenon was demonstrated in Anaplasma phagocytophilum (Levin and Fish, Reference Levin and Fish2000) but not in the closely related Anaplasma marginale (Kocan and de la Fuente, Reference Kocan and de la Fuente2003). In summary, co-feeding transmission has been demonstrated in a variety of tick-borne pathogens including viruses and bacteria.

Co-feeding transmission in B. burgdorferi s. l

The B. burgdorferi s. l. genospecies complex contains a number of pathogens that cause Lyme borreliosis, the most common tick-borne disease in the Northern Hemisphere. Co-feeding transmission has been demonstrated for the three B. burgdorferi s. l. genospecies that are most commonly associated with human Lyme borreliosis: B. burgdorferi sensu stricto (s. s.) (Gern and Rais, Reference Gern and Rais1996; Patrican, Reference Patrican1997; Piesman and Happ, Reference Piesman and Happ2001; Hu et al. Reference Hu, Cheminade, Perret, Weynants, Lobet and Gern2003), Borrelia afzelii (Richter et al. Reference Richter, Allgower and Matuschka2002; Hu et al. Reference Hu, Cheminade, Perret, Weynants, Lobet and Gern2003), and Borrelia garinii (Sato and Nakao, Reference Sato and Nakao1997; Hu et al. Reference Hu, Cheminade, Perret, Weynants, Lobet and Gern2003), as well as Borrelia valaisiana (Hu et al. Reference Hu, Cheminade, Perret, Weynants, Lobet and Gern2003). One reason for the controversial role of co-feeding transmission in Lyme disease is because systemic transmission of Borrelia spirochaetes from the reservoir host to the tick vector is highly efficient. For example, in the North American system of B. burgdorferi s. s. and the tick vector Ixodes scapularis, the systemic transmission rate from competent reservoir hosts such as the white-footed mouse, Peromyscus leucopus, can reach 90% (Donahue et al. Reference Donahue, Piesman and Spielman1987). By contrast, co-feeding transmission in this system was 20-fold lower (5%) and only occurred under very unrealistic tick infestation conditions (mice were infested with ~28 infected nymphs and 200 larvae) (Piesman and Happ, Reference Piesman and Happ2001). Co-feeding transmission of B. burgdorferi s. s. was higher in two other studies where the authors used either an unnatural gerbil reservoir host (18–88%) (Patrican, Reference Patrican1997) or European strains of B. burgdorferi s. s. in combination with Ixodes ricinus ticks (32·5–60·9%) (Gern and Rais, Reference Gern and Rais1996). In the European system of B. afzelii and the tick vector I. ricinus, co-feeding transmission ranged from 1·6 to 55·3% under realistic tick infestation conditions (mice were infested with one infected nymph) (Richter et al. Reference Richter, Allgower and Matuschka2002). A study on field-collected I. ricinus ticks that were mostly infected with B. afzelii found that 95% (105/111) of all laboratory mice produced at least one co-infected tick (Hu et al. Reference Hu, Cheminade, Perret, Weynants, Lobet and Gern2003) but unfortunately, the mouse-specific co-feeding transmission rates were not reported (Hu et al. Reference Hu, Cheminade, Perret, Weynants, Lobet and Gern2003). A study on B. garinii and Ixodes persulcatus ticks found that the co-feeding transmission rates ranged from 6·0 to 29·0% (Sato and Nakao, Reference Sato and Nakao1997). While experimental differences in Borrelia genospecies, tick vector species and reservoir hosts make it difficult to generalize, co-feeding transmission appears to be more efficient in the European system of B. afzelii and I. ricinus than the North American system of B. burgdorferi s. s. and I. scapularis.

The viability of spirochaetes acquired via co-feeding transmission remains an open question. Many studies that measure co-feeding transmission use detection methods such as fluorescent antibody tests or PCR, which cannot establish whether the B. burgdorferi s. l. spirochaetes in the co-feeding ticks are actually alive (Gern and Rais, Reference Gern and Rais1996; Patrican, Reference Patrican1997; Sato and Nakao, Reference Sato and Nakao1997; Richter et al. Reference Richter, Allgower and Matuschka2002). Evidence that co-feeding transmits viable B. burgdorferi s. l. comes from two studies that cultured live spirochaetes from co-feeding ticks (Piesman and Happ, Reference Piesman and Happ2001; Hu et al. Reference Hu, Cheminade, Perret, Weynants, Lobet and Gern2003). However, in both of these studies, the spirochaetes were cultured in Barbour–Stoenner–Kelly (BSK) medium within 1 week of the co-feeding transmission event. In contrast, under natural conditions, Borrelia spirochaetes typically spend many months inside the nymphal tick before infecting a new vertebrate reservoir host. Thus the long-term survival prospects of co-feeding acquired spirochaetes in the tick vector remain unknown. Similarly, whether spirochaetes acquired via co-feeding transmission are infectious to vertebrate reservoir hosts also remains unknown.

ECOLOGY OF CO-FEEDING TRANSMISSION

Larval and nymphal ticks maintain Lyme borreliosis in nature because these two immature tick stages feed on the same suite of reservoir hosts. Larvae (being the younger stage) are an order of magnitude more common than nymphs into which they develop following the larval blood meal. The generational transfer of Borrelia spirochaetes from a few infected nymphs to many uninfected larvae (via the host upon which they are feeding) is the critical life history event that defines the reproductive number (R 0) and the epidemiology of Lyme disease (Randolph, Reference Randolph1998; Tsao, Reference Tsao2009). Transstadial maintenance of the infection, where infected, blood-engorged larvae maintain the infection during the moult and develop into the next generation of Borrelia-infected nymphs, is another essential feature of the spirochaete life cycle. Naive recipient larval ticks can acquire spirochaetes from feeding on an infected reservoir host (host-to-larva systemic transmission) or from feeding next to an infected donor nymph on a bridge host (nymph-to-larva co-feeding transmission). Nymph-to-nymph co-feeding transmission is possible (Patrican, Reference Patrican1997) but is much less common than nymph-to-larva co-feeding transmission. A field study on wild rodents in Slovakia found 12,032 attached larvae and 400 attached nymphs (Randolph et al. Reference Randolph, Miklisova, Lysy, Rogers and Labuda1999). Thus in this particular rodent community, nymph-to-larva co-feeding transmission occurred 30 times more often than nymph-to-nymph transmission and the latter is therefore largely irrelevant to the fitness of tick-borne pathogens. Transovarial transmission has enormous potential to enhance spirochaete fitness because one infected female can produce many infected offsprings. However, two recent studies suggest that previous reports of transovarial transmission in B. burgdorferi s. l. were confounded by co-infection with Borrelia miyamotoi, a recently discovered species that belongs to the relapsing fever-group (Richter et al. Reference Richter, Debski, Hubalek and Matuschka2012; Rollend et al. Reference Rollend, Fish and Childs2013). These new developments therefore suggest that transovarial transmission does not occur in B. burgdorferi s. l. (Richter et al. Reference Richter, Debski, Hubalek and Matuschka2012; Rollend et al. Reference Rollend, Fish and Childs2013). The two key fitness components of B. burgdorferi s. l. pathogens are therefore the number of infected larvae produced via co-feeding transmission and the number of infected larvae produced via systemic transmission.

Synchronous questing activity of immature ticks

Successful co-feeding transmission requires that larval and nymphal ticks feed at the same time and on the same host. Co-feeding transmission therefore has two necessary ecological conditions: synchrony of larval and nymphal host-searching (questing) activity and the co-occurrence of larvae and nymphs on the same host (Randolph et al. Reference Randolph, Gern and Nuttall1996, Reference Randolph, Miklisova, Lysy, Rogers and Labuda1999). Differences in climate between North America and Europe produce contrasting tick activity patterns (phenologies) (Kurtenbach et al. Reference Kurtenbach, Hanincova, Tsao, Margos, Fish and Ogden2006) with important consequences for co-feeding transmission. In North America, immature I. scapularis ticks exhibit asynchronous phenologies; peak nymphal and larval questing activities occur at different times of the year (early and late summer, respectively). By contrast, in Europe, immature I. ricinus ticks are active at the same time from spring to autumn (Craine et al. Reference Craine, Randolph and Nuttall1995; Kurtenbach et al. Reference Kurtenbach, Hanincova, Tsao, Margos, Fish and Ogden2006; Burri et al. Reference Burri, Bastic, Maeder, Patalas and Gern2011). The potential for spirochaete co-feeding transmission is therefore probably much greater in Europe than in North America. A recent study in North America showed that climate-induced differences in the seasonal synchrony of tick questing activity can influence the community of circulating Borrelia strains (Gatewood et al. Reference Gatewood, Liebman, Vourc'h, Bunikis, Hamer, Cortinas, Melton, Cislo, Kitron, Tsao, Barbour, Fish and Diuk-Wasser2009). In the Northeast, a large temporal gap between peak nymphal and peak larval questing activity (i.e. high seasonal asynchrony) favours strains of B. burgdorferi s. s. that are long-lived inside the reservoir host (Gatewood et al. Reference Gatewood, Liebman, Vourc'h, Bunikis, Hamer, Cortinas, Melton, Cislo, Kitron, Tsao, Barbour, Fish and Diuk-Wasser2009). These long-lived strains are also more invasive in humans suggesting that interactions between climate, tick phenology and strain phenotype can have important consequences for the epidemiology of Lyme borreliosis.

Interestingly, climate change is predicted to have different consequences for co-feeding transmission on these two continents. In North America, climate change is expected to speed up the onset of larval activity patterns thereby increasing the scope for co-feeding transmission (Ogden et al. Reference Ogden, Bigras-Poulin, O'Callaghan, Barker, Kurtenbach, Lindsay and Charron2007). In Europe, by contrast, climate change is predicted to disrupt transmission cycles of tick-borne pathogens that are highly dependent on coincident feeding and co-feeding transmission (Randolph and Rogers, Reference Randolph and Rogers2000; Randolph and Sumilo, Reference Randolph, Sumilo, Takken and Knols2007). For example, depending on the climate change scenario, TBEV will be largely eliminated from central Europe by 2050 (Randolph and Rogers, Reference Randolph and Rogers2000; Randolph and Sumilo, Reference Randolph, Sumilo, Takken and Knols2007).

Co-occurrence and aggregation of immature ticks on the same host

Co-occurrence of infected nymphs and susceptible larvae on the same host is another critical ecological condition for co-feeding transmission. Ticks are often highly aggregated on just a few hosts and follow the ‘20/80 Rule’ (Woolhouse et al. Reference Woolhouse, Dye, Smith, Etard, Charlwood, Garnett, Hagan, Hii, Ndhlovu, Quinnell, Watts, Chandiwana and Anderson1997) where 20% of the reservoir hosts feed about 80% of the immature ticks (Randolph et al. Reference Randolph, Miklisova, Lysy, Rogers and Labuda1999; Perkins et al. Reference Perkins, Cattadori, Tagliapietra, Rizzoli and Hudson2003; Devevey and Brisson, Reference Devevey and Brisson2012). In general, those host individuals that feed the greatest number of nymphs also tend to feed and infect the greatest number of larvae (Craine et al. Reference Craine, Randolph and Nuttall1995; Randolph et al. Reference Randolph, Miklisova, Lysy, Rogers and Labuda1999; Brunner and Ostfeld, Reference Brunner and Ostfeld2008). For example, a field study of wild rodents in Slovakia found that 26% of the most heavily infested individuals fed up to 75% of the nymphs and 86% of the larvae (Randolph et al. Reference Randolph, Miklisova, Lysy, Rogers and Labuda1999). A field survey of yellow-necked mouse, Apodemus flavicollis, found that 20% of the mice (mostly adult males) fed 83% of the larvae and hosted 72% of the co-feeding events (Perkins et al. Reference Perkins, Cattadori, Tagliapietra, Rizzoli and Hudson2003). Similarly, a field survey on the wood mouse, Apodemus sylvaticus, found that 20% of the mice hosted all the nymphs and 72% of the larvae (Harrison et al. Reference Harrison, Montgomery and Bown2011). Calculation of the reproductive number (R 0) for tick-borne pathogens such as TBEV suggests that these co-occurrence patterns of immature ticks on the same host increase pathogen fitness by a factor of three in comparison to the null hypothesis of independent larval and nymphal distributions (Randolph et al. Reference Randolph, Miklisova, Lysy, Rogers and Labuda1999). Thus coincident feeding of immature ticks is critical for maintaining and amplifying co-feeding transmission.

There are a variety of reasons why ticks are aggregated on a subset of their hosts. Questing larvae are often highly aggregated in space because they hatch from a single egg batch and have limited dispersal (Steele and Randolph, Reference Steele and Randolph1985; Daniels and Fish, Reference Daniels and Fish1990). Male rodents tend to have higher tick burdens than female rodents because they are bigger and have larger home ranges (Randolph, Reference Randolph1975; Perkins et al. Reference Perkins, Cattadori, Tagliapietra, Rizzoli and Hudson2003). Another reason why male rodents are believed to be susceptible to high tick infestations is because their immune system is suppressed by testosterone (Hughes and Randolph, Reference Hughes and Randolph2001). Estimates of tick burden and coincident aggregation are critical for parameterizing models that estimate the contributions of co-feeding and systemic transmission to the fitness of tick-borne pathogens (Harrison and Bennett, Reference Harrison and Bennett2012).

Mechanics of co-feeding transmission – time and distance

The efficiency of co-feeding transmission of B. burgdorferi s. l. depends on two important factors: the time between larval and nymphal fixation and the distance between the larval and nymphal attachment sites. To measure co-feeding transmission, workers typically place xenodiagnostic larvae on the host at the same time (Patrican, Reference Patrican1997; Sato and Nakao, Reference Sato and Nakao1997; Piesman and Happ, Reference Piesman and Happ2001) or a few days (2–5 days) after attachment of the Borrelia-infected nymphs (Gern and Rais, Reference Gern and Rais1996; Richter et al. Reference Richter, Allgower and Matuschka2002; Hu et al. Reference Hu, Cheminade, Perret, Weynants, Lobet and Gern2003). In the B. afzeliiI. ricinus system, co-feeding transmission increased from 0·0 to 55·3% as the duration of nymphal attachment before larval attachment increased from 0 to 3 days (Richter et al. Reference Richter, Allgower and Matuschka2002). Co-feeding transmission on a bridge host can take place even when the nymphs and larvae are not attached at the same time. In B. burgdorferi s. s. and the tick vector I. ricinus, co-feeding transmission from the site of infected nymphal attachment (the back of the mouse) occurred for 14 days, even after infected nymphs had detached, while systemic transmission from a distant site (the head) was not observed until 29 days following nymphal attachment (Gern and Rais, Reference Gern and Rais1996). Thus systemic transmission is separated in time from co-feeding transmission.

The distance between co-feeding ticks is another factor that influences the efficiency of co-feeding transmission. Workers often place nymphs and larvae in capsules that are fixed to the skin of the bridge host to manipulate the distance at which ticks co-feed from each other (Gern and Rais, Reference Gern and Rais1996; Sato and Nakao, Reference Sato and Nakao1997; Hu et al. Reference Hu, Cheminade, Perret, Weynants, Lobet and Gern2003). In the B. afzeliiI. ricinus system, co-feeding transmission declines from 55·3 to 25·6 to 6·3% as the distance between nymphs and larvae increases from 0·0 to 1·0 to 2·0 cm (Richter et al. Reference Richter, Allgower and Matuschka2002). This spatial constraint would appear to reduce the importance of co-feeding transmission to spirochaete fitness. However, ticks do not randomly select feeding attachment sites and are often spatially clustered on the host. Most immature Ixodes ticks are found on the ears, head and neck of their rodent hosts (Randolph, Reference Randolph1975; Craine et al. Reference Craine, Randolph and Nuttall1995; Schmidt et al. Reference Schmidt, Ostfeld and Schauber1999), presumably to avoid host grooming, which represents a significant source of tick mortality (Shaw et al. Reference Shaw, Keesing, McGrail and Ostfeld2003; Keesing et al. Reference Keesing, Brunner, Duerr, Killilea, LoGiudice, Schmidt, Vuong and Ostfeld2009). A field survey of squirrels in England found that 95% of all immature I. ricinus ticks were found on the ears (Craine et al. Reference Craine, Randolph and Nuttall1995). Randolph suggested that ~45% of feeding ticks are within ~1 cm of each other on the rodent host, thereby greatly facilitating co-feeding transmission (Randolph, Reference Randolph2011). Spatial clustering of I. ricinus ticks was also observed on sheep in the northwest UK where 90% of the ticks were found on 20% of the sheep surface area (the part that was not covered by wool) (Ogden et al. Reference Ogden, Hailes and Nuttall1998a ). In these sheep populations, co-feeding is believed to be the predominant mode of spirochaete transmission (Ogden et al. Reference Ogden, Nuttall and Randolph1997). A study on roe deer found that 54% of the total tick load was found on only 12% of the total surface area of the animals (Kiffner et al. Reference Kiffner, Lodige, Alings, Vor and Ruhe2011). Thus spatial clustering of I. ricinus larval and nymphal ticks is commonly observed in both rodents and ungulates.

In some tick species, co-occurrence on the same host and spatial clustering of ticks on the same host surfaces appear to be mediated by pheromones (Sonenshine, Reference Sonenshine2004). Spatial clustering may also facilitate cooperative feeding among ticks as demonstrated in several species of ixodid ticks (Wang et al. Reference Wang, Paesen, Nuttall and Barbour1998; Rechav and Nuttall, Reference Rechav and Nuttall2000; Wang et al. Reference Wang, Hails, Cui and Nuttall2001b ). In I. ricinus for example, nymphs that co-fed with larvae had higher feeding success and greater engorgement weights than nymphs that did not co-feed with larvae (Ogden et al. Reference Ogden, Kurtenbach and Nuttall1998b ). Cooperative feeding, by allowing vectors to pool their saliva, may enhance the immunomodulatory manipulation of the host organism. If the immunomodulatory constituents of tick saliva are costly, cooperative feeding could increase the cost-benefit ratio of resource extraction from the host relative to per capita investment in tick saliva production. Avoidance of host grooming behaviour, pheromone-induced aggregation and cooperative feeding are different mechanisms that enhance the spatial clustering of ticks on the same host. In turn, these spatial clustering mechanisms cause ticks to feed on the same patch of skin thereby enhancing co-feeding transmission of spirochaetes.

MOLECULAR MECHANISMS OF CO-FEEDING TRANSMISSION

The molecular mechanisms that facilitate co-feeding transmission are better understood for TBEV than for Borrelia pathogens. Co-feeding transmission of TBEV appears to be mediated by migratory leucocytes. Langerhans cells, the dendritic cells that reside in the skin, appear to be recruited to the tick-feeding site where they acquire TBEV (Labuda et al. Reference Labuda, Zuffova, Kozuch, Fuchsberger, Austyn, Lysy and Nuttall1996). Infected Langerhans cells are believed to transmit the virus to T lymphocytes in the local lymph nodes (Nuttall, Reference Nuttall1999; Nuttall and Labuda, Reference Nuttall and Labuda2003). The infected T lymphocytes are then recruited to the feeding sites of uninfected ticks thereby completing the co-feeding transmission cycle of TBEV (Nuttall, Reference Nuttall1999; Nuttall and Labuda, Reference Nuttall and Labuda2003). Perhaps migratory leucocytes play a similar role in the co-feeding transmission of intracellular tick-borne bacteria such as A. phagocytophilum (Levin and Fish, Reference Levin and Fish2000). Borrelia, being an extracellular bacterium, is therefore unlikely to use migratory leucocytes for transmission between co-feeding ticks (although there is some evidence that spirochaetes can be re-cultured from phagocytes following transport to the lymphatic system (Montgomery et al. Reference Montgomery, Nathanson and Malawista1993)). Borrelia spirochaetes likely rely on their periplasmic flagella that allow them to migrate autonomously through the tissues of the reservoir host (Charon et al. Reference Charon, Cockburn, Li, Liu, Miller, Miller, Motaleb and Wolgemuth2012). Co-feeding transmission of Borrelia spirochaetes may also benefit from saliva-assisted transmission (SAT) (Nuttall and Labuda, Reference Nuttall and Labuda2004), as this phenomenon is known to enhance co-feeding transmission of tick-borne viruses (Labuda et al. Reference Labuda, Williams, Jones and Nuttall1993c ).

Saliva-assisted transmission and co-feeding transmission

Ticks use their saliva to modulate the haemostatic, inflammatory and immune responses of the hosts and thereby optimize blood uptake (Brossard and Wikel, Reference Brossard and Wikel2004). Tick saliva contains a wide variety of pharmacologically active agents that suppress both the innate and the acquired immune system of the vertebrate host (Nuttall, Reference Nuttall1999; Nuttall and Labuda, Reference Nuttall and Labuda2004; Randolph, Reference Randolph2009). Tick saliva creates a zone of immunosuppression around the site of tick feeding that is beneficial to both the ticks and tick-borne pathogens. SAT thus refers to the phenomenon where saliva of the arthropod vector increases the transmission of vector-borne pathogens (Ribeiro, Reference Ribeiro1995). SAT and co-feeding transmissions are clearly connected; the pooled saliva of ticks feeding in close spatiotemporal proximity creates an environment that is propitious for co-feeding transmission. The two concepts are so closely linked that previous reviews considered co-feeding transmission as indirect evidence for SAT (Nuttall and Labuda, Reference Nuttall and Labuda2004).

The salivary gland extracts (SGE) from I. ricinus ticks suppresses both the innate and acquired immune response in their rodent hosts (Ribeiro and Spielman, Reference Ribeiro and Spielman1986; Ribeiro, Reference Ribeiro1987; Ribeiro et al. Reference Ribeiro, Weis and Telford1990; Mejri et al. Reference Mejri, Rutti and Brossard2002; Pechová et al. Reference Pechová, Stepanova, Kovar, Kopecky, Kovár and Kopecký2002; Guo et al. Reference Guo, Booth, Paley, Wang, DePonte, Fikrig, Narasimhan and Montgomery2009). This tick-induced immunosuppression is beneficial to the survival and fitness of Borrelia pathogens in the vertebrate host. For example, tick SGE from I. ricinus inhibited the ability of mouse macrophages to kill B. afzelii (Kuthejlová et al. Reference Kuthejlová, Kopecky, Stepanova, Macela, Kopecký and Stepánová2001). Gern et al. (Reference Gern, Schaible and Simon1993) provided some of the earliest evidence that the mode of inoculation (tick bite vs needle inoculation) influenced the dynamics of Borrelia infection and the immune response in laboratory mice. Later studies generated additional evidence that Ixodes tick SGE increase infectiousness and transmission of Borrelia pathogens. For example, B. burgdorferi s. s. uses its outer surface protein C (OspC) to bind the tick salivary gland protein Salp15, which allows the pathogen to evade the rodent immune response during the initial phase of the infection (Ramamoorthi et al. Reference Ramamoorthi, Narasimhan, Pal, Bao, Yang, Fish, Anguita, Norgard, Kantor, Anderson, Koski and Fikrig2005). Co-inoculation of Borrelia pathogens with Ixodes tick SGE increased the spirochaete load in the tissues of laboratory rodents (Zeidner et al. Reference Zeidner, Gern, Piesman, Schneider and Nuncio2002). Other studies have shown that spirochaete load in rodent tissues correlates with infectiousness (Wang et al. Reference Wang, Ojaimi, Iyer, Saksenberg, McClain, Wormser and Schwartz2001a ) and mouse-to-tick transmission (Raberg, Reference Raberg2012). Interestingly, the SAT effect was specific for the particular combination of Ixodes tick vector and Borrelia pathogen; I. ricinus SGE increased spirochaete load of a European but not an American Borrelia genospecies and vice versa for I. scapularis SGE (Zeidner et al. Reference Zeidner, Gern, Piesman, Schneider and Nuncio2002). Another study found that co-inoculation of B. afzelii spirochaetes with I. ricinus SGE (via needle) resulted in efficient mouse-to-tick transmission to co-feeding nymphs (57%) whereas there was no mouse-to-tick transmission in the control mice that were inoculated with B. afzelii spirochaetes alone (Pechová et al. Reference Pechová, Stepanova, Kovar, Kopecky, Kovár and Kopecký2002). Thus tick-salivary gland products increase both tick-to-mouse and mouse-to-tick transmission rates of Borrelia pathogens.

Co-feeding transmission of Borrelia pathogens is different from TBEV because spirochaetes are capable of surviving in the skin for a substantial period of time following inoculation by tick bite. Previous work on B. burgdorferi s. s. showed that Ixodes ticks deposit spirochaetes into the skin where they multiply locally for about 1 week before disseminating to the rest of the body and establishing a systemic infection (Shih et al. Reference Shih, Spielman, Pollack and Telford1992). More recent work found evidence for tick SGE effects on spirochaete population growth (Rudolf et al. Reference Rudolf, Hubalek and Hubálek2003, Reference Rudolf, Sikutova, Kopecky and Hubalek2010) and chemotactic behaviour (Shih et al. Reference Shih, Chao and Yu2002), and both of these phenomena could facilitate co-feeding transmission. All three pathogenic Borrelia genospecies (B. garinii, B. afzelii and B. burgdorferi s. s.) grow faster in vitro in the presence of I. ricinus SGE (Rudolf et al. Reference Rudolf, Hubalek and Hubálek2003, Reference Rudolf, Sikutova, Kopecky and Hubalek2010). Again, the SAT effect is specific for the tick vector and SGE from non-competent vector ticks such as Dermacentor reticulatus did not enhance spirochaete population growth in vitro (Rudolf et al. Reference Rudolf, Hubalek and Hubálek2003). With respect to chemotaxis, work on B. burgdorferi s. s. found that spirochaetes can migrate at substantial speeds (2 cm/day) through semi-solid media towards Ixodes tick SGE (Shih et al. Reference Shih, Chao and Yu2002). The hallmark symptom of Lyme disease, erythema migrans, is further evidence that Borrelia pathogens migrate through the skin before disseminating and establishing a systemic infection. Another study found that B. burgdorferi s. s. spirochaetes respond to vertebrate host neuroendocrine stress hormones such as epinephrine and norepinephrine that are likely to be released at the tick feeding site (Scheckelhoff et al. Reference Scheckelhoff, Telford, Wesley and Hu2007). Taken together, these studies suggest that the adaptive effects of SGE on spirochaete growth and chemotactic behaviour could easily be co-opted at the host-nymph-larva-pathogen interface to produce co-feeding transmission.

ADAPTIVE SIGNIFICANCE OF CO-FEEDING TRANSMISSION

Theoretical models of co-feeding transmission

The reproductive number of a parasite, R 0, is a critical parameter in epidemiology. For directly transmitted infectious diseases, R 0 is the number of secondary cases produced by a single infected individual when the host population is entirely susceptible. R 0 therefore measures the capacity of a parasite to invade a population of susceptible hosts. For a tick-borne disease, the interpretation of R 0 is complicated by the fact that there is a tick-to-host and a host-to-tick transmission step. However, in this case R 0 represents the number of infected ticks produced by one infected tick in the previous generation. Recent theoretical work has used the next-generation matrix method to calculate R 0 for tick-borne pathogens (Hartemink et al. Reference Hartemink, Randolph, Davis and Heesterbeek2008; Harrison et al. Reference Harrison, Montgomery and Bown2011; Harrison and Bennett, Reference Harrison and Bennett2012). These theoretical analyses generally show that whereas co-feeding transmission is critical for TBEV, systemic transmission is sufficient for Borrelia pathogens to invade a population of susceptible hosts (Hartemink et al. Reference Hartemink, Randolph, Davis and Heesterbeek2008; Harrison et al. Reference Harrison, Montgomery and Bown2011; Harrison and Bennett, Reference Harrison and Bennett2012). When ticks had a coincident, aggregated distribution, the value of R 0 increased by 2·07 to 6·68% depending on the proportion of competent hosts (10–100%) from which the ticks derive their meal (Harrison and Bennett, Reference Harrison and Bennett2012). This analysis suggests that a mutant genotype capable of both systemic and co-feeding transmission would be able to outcompete and eventually displace a resident genotype that uses systemic transmission alone. Thus co-feeding transmission may give Borrelia pathogens a competitive advantage in the context of mixed infections (see below).

Randolph et al. (Reference Randolph, Gern and Nuttall1996) were the first to point out that the duration of infection is the main reason why TBEV (2 days) is critically dependent on co-feeding transmission whereas Borrelia pathogens (120 days) are not. Elasticity analysis of the next generation matrices of tick-borne pathogens have confirmed that R 0 value of tick-borne pathogens is highly dependent on the duration of systemic infection (Hartemink et al. Reference Hartemink, Randolph, Davis and Heesterbeek2008). Changing the duration of systemic infection from 120 days to 2 days essentially switched the major contribution to R 0 from systemic to co-feeding transmission (Randolph et al. Reference Randolph, Gern and Nuttall1996). It should be pointed out that all recent theories (Hartemink et al. Reference Hartemink, Randolph, Davis and Heesterbeek2008; Harrison et al. Reference Harrison, Montgomery and Bown2011; Harrison and Bennett, Reference Harrison and Bennett2012) have used the same parameter estimates from the 1996 analysis by Randolph et al. All these theoretical studies therefore assume that the average duration of Borrelia infection is 120 days and that the host-to-tick transmission rate is 50% and constant over the age of the infection (Hartemink et al. Reference Hartemink, Randolph, Davis and Heesterbeek2008; Harrison et al. Reference Harrison, Montgomery and Bown2011; Harrison and Bennett, Reference Harrison and Bennett2012). These parameter estimates were taken from early studies on competent rodent reservoir hosts that documented chronic infection and high rates of mouse-to-tick transmission (Donahue et al. Reference Donahue, Piesman and Spielman1987; Gern et al. Reference Gern, Siegenthaler, Hu, Leuba-Garcia, Humair and Moret1994). However, other studies have shown that the mouse-to-tick transmission rate can decrease rapidly over time (Lindsay et al. Reference Lindsay, Barker, Surgeoner, McEwen and Campbell1997; Derdakova et al. Reference Derdakova, Dudioak, Brei, Brownstein, Schwartz and Fish2004; Hanincova et al. Reference Hanincova, Ogden, Diuk-Wasser, Pappas, Iyer, Fish, Schwartz and Kurtenbach2008). For example, mouse-to-tick transmission of B. burgdorferi s. s. strain B348 declined from 80 to 0% over 42 days (Derdakova et al. Reference Derdakova, Dudioak, Brei, Brownstein, Schwartz and Fish2004). Another study found that mouse-to-tick transmission declined from 75 to 26% in only 21 days (Lindsay et al. Reference Lindsay, Barker, Surgeoner, McEwen and Campbell1997). Incorporating this shorter duration of infectiousness would obviously increase the importance of co-feeding transmission to the fitness of Borrelia pathogens.

Life history perspective of co-feeding transmission

From a life history theory perspective, the distinction between co-feeding and systemic transmission is similar to the trade-off between early and late reproduction that is common to all organisms (Stearns, Reference Stearns1992). On the one hand, systemic transmission is more efficient than co-feeding transmission suggesting that spirochaetes should maximize investment in systemic transmission to achieve the highest possible fitness. On the other hand, vulnerable reservoir hosts such as rodents have many sources of mortality (accidents, predators and disease) and dead rodents cannot transmit systemic infections. In addition, systemically infected individuals may disperse to new habitats that do not support larval ticks to complete the systemic infection cycle. Thus investment in co-feeding transmission may represent a bet-hedging strategy for the spirochaete because the future is uncertain and a systemic infection may not always bear fruit. As mentioned previously, numerous studies on B. burgdorferi s. s. have shown that the efficiency of mouse-to-larva transmission decreases with the age of the systemic infection in the reservoir host (Lindsay et al. Reference Lindsay, Barker, Surgeoner, McEwen and Campbell1997; Derdakova et al. Reference Derdakova, Dudioak, Brei, Brownstein, Schwartz and Fish2004; Hanincova et al. Reference Hanincova, Ogden, Diuk-Wasser, Pappas, Iyer, Fish, Schwartz and Kurtenbach2008). Thus the fitness advantage of systemic transmission appears to decline with the age of the infection.

Co-feeding transmission and the evasion of host immunity

Co-feeding transmission allows tick-borne pathogens to escape the host immune response that is directed at systemic infections. Immune evasion via co-feeding was first demonstrated in TBEV; the virus was still able to achieve co-feeding transmission on rodents that had developed virus-specific neutralizing antibodies in response to an earlier viraemic infection (Labuda et al. Reference Labuda, Kozuch, Zuffova, Eleckova, Hails and Nuttall1997). From an epidemiological perspective, hosts that had acquired resistance to systemic infection were still competent for co-feeding transmission.

The host immune system of vertebrate reservoir hosts likewise poses a major challenge for B. burgdorferi s. l. pathogens. Both the innate and the acquired arms of the vertebrate immune system can prevent the establishment of systematic spirochaete infections. The innate complement system is a collection of host serum proteins that assemble on the pathogen surface to form the so-called membrane attack complex, which is capable of puncturing the plasma membranes resulting in cell lysis and pathogen death. In the European Lyme disease system, host complement appears to play an important role in structuring associations between Borrelia pathogens and their vertebrate hosts (Kurtenbach et al. Reference Kurtenbach, Sewell, Ogden, Randolph and Nuttall1998b , Reference Kurtenbach, De Michelis, Etti, Schafer, Sewell, Brade and Kraiczy2002a ). Borrelia afzelii and B. burgdorferi s. s. are tolerant of rodent but not bird complement (Kurtenbach et al. Reference Kurtenbach, Sewell, Ogden, Randolph and Nuttall1998b , Reference Kurtenbach, De Michelis, Etti, Schafer, Sewell, Brade and Kraiczy2002a ) and are mostly found in rodent reservoir hosts (Humair et al. Reference Humair, Péter, Wallich and Gern1995; Humair and Gern, Reference Humair and Gern1998; Kurtenbach et al. Reference Kurtenbach, Peacey, Rijpkema, Hoodless, Nuttall and Randolph1998a ; Huegli et al. Reference Huegli, Hu, Humair, Wilske and Gern2002; Hanincova et al. Reference Hanincova, Schafer, Etti, Sewell, Taragelova, Ziak, Labuda and Kurtenbach2003a ). Conversely, B. garinii and B. valaisiana are tolerant of bird but not rodent complement (Kurtenbach et al. Reference Kurtenbach, Sewell, Ogden, Randolph and Nuttall1998b , Reference Kurtenbach, De Michelis, Etti, Schafer, Sewell, Brade and Kraiczy2002a ) and are mostly found in birds (Humair et al. Reference Humair, Postic, Wallich and Gern1998; Kurtenbach et al. Reference Kurtenbach, Peacey, Rijpkema, Hoodless, Nuttall and Randolph1998a ,  Reference Kurtenbach, Schafer, Sewell, Peacey, Hoodless, Nuttall and Randolph2002b ; Hanincova et al. Reference Hanincova, Taragelova, Koci, Schafer, Hails, Ullmann, Piesman, Labuda and Kurtenbach2003b ; Taragel'ová et al. Reference Taragel'ová, Koci, Hanincova, Kurtenbach, Derdakova, Ogden, Hanincová, Derdáková, Literák, Kocianová and Labuda2008). Vertebrate complement therefore plays an important role in restricting the range of reservoir hosts that are competent for systemic transmission.

Since its initial discovery, numerous authors have suggested that co-feeding transmission may allow Borrelia pathogens to derive some fitness gains from the otherwise incompetent hosts (Randolph et al. Reference Randolph, Gern and Nuttall1996; Gern et al. Reference Gern, Estrada-Pena, Frandsen, Gray, Jaenson, Jongejan, Kahl, Korenberg, Mehl and Nuttall1998) and there is some evidence to suggest that this is the case. For example, B. garinii and B. valaisiana achieved transmission between immature Ixodes ticks co-feeding on laboratory mice even though these Borrelia genospecies are generally killed by rodent complement (Sato and Nakao, Reference Sato and Nakao1997; Hu et al. Reference Hu, Cheminade, Perret, Weynants, Lobet and Gern2003). A recent study on birds found that ticks co-feeding with other ticks were four times more likely to be infected with B. afzelii (Hasle, Reference Hasle2013). To date, the most convincing example comes from the northwest UK where co-feeding I. ricinus ticks maintain Borrelia pathogens in populations of sheep that are otherwise refractory to developing systemic spirochaete infections (Ogden et al. Reference Ogden, Nuttall and Randolph1997).

Cervids are of particular interest with respect to co-feeding transmission because these animals are known to feed a large number of both immature and adult ticks (Jaenson and Talleklint, Reference Jaenson and Talleklint1992; Matuschka et al. Reference Matuschka, Heiler, Eiffert, Fischer, Lotter and Spielman1993). Recent work using host blood meal identification has confirmed the importance of deer as hosts for immature ticks in both North America and Europe. These studies found that 26·2–40·0% of all questing Ixodes nymphs obtained their blood meals from deer (and related artiodactyls) (Morán Cadenas et al. Reference Morán Cadenas, Rais, Humair, Douet, Moret and Gern2007; Scott et al. Reference Scott, Harmon, Tsao, Jones and Hickling2012). Earlier work on cervids suggested that these animals rarely transmitted B. burgdorferi s. l. to Ixodes ticks (Telford et al. Reference Telford, Mather, Moore, Wilson and Spielman1988; Jaenson and Talleklint, Reference Jaenson and Talleklint1992; Matuschka et al. Reference Matuschka, Heiler, Eiffert, Fischer, Lotter and Spielman1993) but these studies did not consider the possibility of co-feeding transmission. A recent field study found that all stages of I. ricinus were highly clustered on roe deer suggesting that these animals could provide a platform for co-feeding transmission (Kiffner et al. Reference Kiffner, Lodige, Alings, Vor and Ruhe2011). An earlier field study on a variety of cervids found that 28·0% (14/50) of the animals had skin biopsies that tested positive for B. burgdorferi s. l. spirochaetes (Pichon et al. Reference Pichon, Gilot and Perez-Eid2000). This study suggested that Borrelia spirochaetes can survive in cervid skin for a considerable period of time because the animals were shot in the winter when there is no tick questing activity (Pichon et al. Reference Pichon, Gilot and Perez-Eid2000). A study on sika deer found that I. persulcatus ticks co-feeding on deerskin had a prevalence of B. burgdorferi s. l. that was five times higher than the background prevalence in questing nymphs (Kimura et al. Reference Kimura, Isogai, Isogai, Kamewaka, Nishikawa, Ishii and Fujii1995). The authors also showed that the spirochaetes in the sika deer-derived ticks were viable by culturing them in BSK medium (Kimura et al. Reference Kimura, Isogai, Isogai, Kamewaka, Nishikawa, Ishii and Fujii1995). This result was important because other in vitro studies have shown that Borrelia pathogens are generally killed by the ungulate complement (Kurtenbach et al. Reference Kurtenbach, Sewell, Ogden, Randolph and Nuttall1998b , Reference Kurtenbach, De Michelis, Etti, Schafer, Sewell, Brade and Kraiczy2002a ). Host blood meal identification in questing ticks has found contradictory results with respect to whether deer can transmit viable spirochaete infections (Gray et al. Reference Gray, Kirstein, Robertson, Stein and Kahl1999; Pichon et al. Reference Pichon, Egan, Rogers and Gray2003, Reference Pichon, Rogers, Egan and Gray2005; Morán Cadenas et al. Reference Morán Cadenas, Rais, Humair, Douet, Moret and Gern2007). An earlier study in Ireland found that all nymphs that had fed on deer were devoid of Borrelia spirochaetes (Gray et al. Reference Gray, Kirstein, Robertson, Stein and Kahl1999). In contrast, a later study in Switzerland, found that that 18·4% (16/87) of all infections with B. burgdorferi s. l. occurred in nymphal ticks that had fed on artiodactyls (deer and chamois) (see Table 4 in Morán Cadenas et al. Reference Morán Cadenas, Rais, Humair, Douet, Moret and Gern2007). In summary, whereas earlier studies concluded that deer rarely transmitted B. burgdorferi s. l. to feeding ticks (Telford et al. Reference Telford, Mather, Moore, Wilson and Spielman1988; Jaenson and Talleklint, Reference Jaenson and Talleklint1992; Matuschka et al. Reference Matuschka, Heiler, Eiffert, Fischer, Lotter and Spielman1993) the more recent work on host blood meal identification suggests that cervids can transmit viable spirochaete infections to Ixodes nymphs (Morán Cadenas et al. Reference Morán Cadenas, Rais, Humair, Douet, Moret and Gern2007). The host blood meal identification work currently suffers from low sensitivity (the blood meal is not identifiable for many questing ticks) and so the sample sizes are still relatively low. Future studies will hopefully establish with more certainty whether co-feeding transmission on cervids makes an important contribution to Borrelia fitness.

The acquired immune response can also prevent the establishment of systemic infections in otherwise competent reservoir hosts. Active and passive immunization of rodents with Borrelia pathogens induces an antibody response that prevents secondary infection by antigenically similar spirochaete strains (Johnson et al. Reference Johnson, Kodner and Russell1986a , Reference Johnson, Kodner and Russell b ; Piesman et al. Reference Piesman, Dolan, Happ, Luft, Rooney, Mather and Golde1997; Barthold Reference Barthold1999). In a natural population of P. leucopus mice, the anti-Borrelia antibody profile becomes increasingly hostile to new systemic infections over the course of the summer (Bunikis et al. Reference Bunikis, Tsao, Luke, Luna, Fish and Barbour2004). Thus the likelihood that a tick-borne spirochaete can find a susceptible reservoir host becomes vanishingly small at the end of the summer. However, tick-borne Borrelia pathogens may still be able to derive some fitness gains from immune hosts if co-feeding transmission allows spirochaetes to escape the antibody response induced against a previous infection. A recent study on another tick-borne bacterial pathogen, the gram-negative, intracellular A. phagocytophilum, found that acquired immunity in P. leucopus reduced but did not eliminate co-feeding transmission (Levin and Fish, Reference Levin and Fish2000). Surprisingly, to date, no one has tested whether acquired immunity reduces the efficiency of co-feeding transmission in Borrelia pathogens. The demonstration that acquired immunity blocks systemic but not co-feeding transmission would demonstrate the adaptive advantage of the latter in the context of acquired immunity in the vertebrate host.

Advantage of co-feeding transmission in multiple infections

Co-feeding may be particularly important in the context of mixed infections where competition among strains will select for any additional transmission advantage. Previous studies have repeatedly shown that mixed infections of Borrelia strains are common in both the tick vector (Qiu et al. Reference Qiu, Bosler, Campbell, Ugine, Wang, Luft and Dykhuizen1997, Reference Qiu, Dykhuizen, Acosta and Luft2002; Wang et al. Reference Wang, Dykhuizen, Qiu, Dunn, Bosler and Luft1999; Pérez et al. Reference Pérez, Kneubühler, Rais, Jouda and Gern2011; MacQueen et al. Reference MacQueen, Lubelczyk, Elias, Cahill, Mathers, Lacombe, Rand and Smith2012) and the rodent reservoir (Brisson and Dykhuizen, Reference Brisson and Dykhuizen2004; Swanson and Norris, Reference Swanson and Norris2008; Pérez et al. Reference Pérez, Kneubühler, Rais, Jouda and Gern2011; Andersson et al. Reference Andersson, Scherman, Raberg and Råberg2013). A recent experimental infection study found that there was genetic variation in co-feeding transmission among nine strains of B. afzelii (Tonetti and Gern, Reference Tonetti and Gern2011). Of the six strains that were capable of this mode of transmission, the efficacy of co-feeding transmission ranged between 3·8 and 66·2% (Tonetti and Gern, Reference Tonetti and Gern2011). The B. afzelii strain that had the highest rate of co-feeding transmission (strain YU) had been discovered in a previous field study where it dominated the community of B. afzelii strains at the site with the higher level of coincident feeding between nymphal and larval ticks (Pérez et al. Reference Pérez, Kneubühler, Rais, Jouda and Gern2011). This field study thus suggested that co-feeding transmission can shape the community of B. afzelii strains, although there are alternative explanations (Pérez et al. Reference Pérez, Kneubühler, Rais, Jouda and Gern2011). For example, strains with high co-feeding transmission also have high tick-to-host and systemic (host-to-tick) transmission (Tonetti and Gern, Reference Tonetti and Gern2011) suggesting that some B. afzelii strains are simply better at all the components of the spirochaete life cycle. The demonstration that there is genetic variation in co-feeding transmission among Borrelia strains is important because it shows that this trait can evolve by natural selection (Tonetti and Gern, Reference Tonetti and Gern2011).

Co-feeding facilitates co-occurrence of ecologically separated Borrelia species

Co-feeding transmission may facilitate encounters between Borrelia species that occupy different ecological niches in the community of vertebrate reservoir hosts. In Europe, as explained previously, the two most common Borrelia species, B. afzelii and B. garinii, are adapted to rodents and birds, respectively (Gern and Humair, Reference Gern and Humair1998; Humair and Gern, Reference Humair and Gern2000; Gern and Humair, Reference Gern, Humair, Gray, Kahl, Lane and Stanek2002), and this host-pathogen specificity is mediated by vertebrate complement (Kurtenbach et al. Reference Kurtenbach, Sewell, Ogden, Randolph and Nuttall1998b , Reference Kurtenbach, De Michelis, Etti, Schafer, Sewell, Brade and Kraiczy2002a ). Statistical analysis of the frequencies of single and double infections in wild ticks supports the hypothesis that B. afzelii and B. garinii occupy different ecological niches (Kurtenbach et al. Reference Kurtenbach, De Michelis, Sewell, Etti, Schafer, Hails, Collares-Pereira, Santos-Reis, Hanincova, Labuda, Bormane and Donaghy2001; Pichon et al. Reference Pichon, Egan, Rogers and Gray2003; Herrmann et al. Reference Herrmann, Gern and Voordouw2013). However, this ecological separation is not 100% complete and the two Borrelia species, by virtue of being common, encounter each other in the tick vector with appreciable frequency (Kurtenbach et al. Reference Kurtenbach, De Michelis, Sewell, Etti, Schafer, Hails, Collares-Pereira, Santos-Reis, Hanincova, Labuda, Bormane and Donaghy2001; Pichon et al. Reference Pichon, Egan, Rogers and Gray2003; Herrmann et al. Reference Herrmann, Gern and Voordouw2013). Co-feeding transmission is a plausible explanation for these co-infected nymphs (Kurtenbach et al. Reference Kurtenbach, De Michelis, Sewell, Etti, Schafer, Hails, Collares-Pereira, Santos-Reis, Hanincova, Labuda, Bormane and Donaghy2001; Pichon et al. Reference Pichon, Egan, Rogers and Gray2003; Herrmann et al. Reference Herrmann, Gern and Voordouw2013). For example, a larva may co-feed with a B. garinii-infected nymph on a B. afzelii-infected rodent reservoir host. In this example, the larva acquires B. garinii from the co-feeding nymph and B. afzelii from the rodent reservoir. The larval tick also ingests the host complement, which is active in the tick midgut (Papatheodorou and Brossard, Reference Papatheodorou and Brossard1987). The complement hypothesis of vertebrate host-Borrelia pathogen specificity predicts that the complement of the reservoir host (i.e. the rodent) would reduce the spirochaete load of the co-feeding-acquired Borrelia species (i.e. B. garinii) inside the larval tick. Interestingly, a recent study on the joint spirochete loads of co-infecting Borrelia species inside I. ricinus nymphs found evidence consistent with this complement hypothesis (Herrmann et al. Reference Herrmann, Gern and Voordouw2013). In summary, co-feeding transmission explains the co-occurrence in nymphs of Borrelia species that occupy different niches in the community of vertebrate hosts. These occasional encounters in the tick vector can have important macro-evolutionary consequences for Borrelia pathogens. For example, genetic analysis of the ospC gene in B. burgdorferi s. s., B. afzelii and B. garinii, found numerous instances of horizontal transfer between these three Borrelia species (Baranton et al. Reference Baranton, Seinost, Theodore, Postic and Dykhuizen2001). Thus co-feeding transmission may facilitate genetic exchange between Borrelia pathogens that are otherwise genetically isolated.

Concluding remarks

Future studies should investigate co-feeding transmission in the Lyme disease systems where it is likely to be important. The synchronized phenologies of immature I. ricinus ticks in Europe and the common occurrence of nymphal and larval ticks on the same host suggest that co-feeding transmission is more important in European than North American Lyme disease systems. Previous studies on B. afzelii and the ease of working with rodent models suggest that the B. afzelii pathogen–I. ricinus tick vector–is the most tractable system for studying the ecological significance of co-feeding transmission. Future studies should test whether co-feeding transmission allows Borrelia pathogens to escape the acquired immune response of their vertebrate hosts and whether this mode of transmission confers a fitness advantage in the context of mixed infections.

ACKNOWLEDGEMENTS

Thanks to three anonymous reviewers for comments on this manuscript. A special thanks to Lise Gern for her comments and support in writing this manuscript.

FINANCIAL SUPPORT

This work was supported by a grant from the Swiss National Science Foundation (FN 31003A_141153).

References

REFERENCES

Alekseev, A. N. and Chunikhin, S. P. (1990). The exchange of the tick-borne encephalitis virus between ixodid ticks feeding jointly on animals with a subthreshold level of viremia. Meditsinskaia Parazitologiia (Mosk) 2, 4850.Google Scholar
Andersson, M., Scherman, K., Raberg, L. and Råberg, L. (2013). Multiple-strain infections of Borrelia afzelii: a role for within-host interactions in the maintenance of antigenic diversity? The American Naturalist 181, 545554.CrossRefGoogle ScholarPubMed
Baranton, G., Seinost, G., Theodore, G., Postic, D. and Dykhuizen, D. (2001). Distinct levels of genetic diversity of Borrelia burgdorferi are associated with different aspects of pathogenicity. Research in Microbiology 152, 149156.Google Scholar
Barthold, S. W. (1999). Specificity of infection-induced immunity among Borrelia burgdorferi sensu lato species. Infection and Immunity 67, 3642.Google Scholar
Brisson, D. and Dykhuizen, D. E. (2004). ospC diversity in Borrelia burgdorferi: different hosts are different niches. Genetics 168, 713722.CrossRefGoogle ScholarPubMed
Brossard, M. and Wikel, S. K. (2004). Tick immunobiology. Parasitology 129(Suppl), S161176.CrossRefGoogle ScholarPubMed
Brunner, J. L. and Ostfeld, R. S. (2008). Multiple causes of variable tick burdens on small-mammal hosts. Ecology 89, 22592272.Google Scholar
Bunikis, J., Tsao, J., Luke, C. J., Luna, M. G., Fish, D. and Barbour, A. G. (2004). Borrelia burgdorferi infection in a natural population of Peromyscus leucopus mice: a longitudinal study in an area where Lyme borreliosis is highly endemic. Journal of Infectious Diseases 189, 15151523.CrossRefGoogle Scholar
Burri, C., Bastic, V., Maeder, G., Patalas, E. and Gern, L. (2011). Microclimate and the zoonotic cycle of tick-borne encephalitis virus in Switzerland. Journal of Medical Entomology 48, 615627.CrossRefGoogle ScholarPubMed
Charon, N., Cockburn, A., Li, C., Liu, J., Miller, K., Miller, M., Motaleb, M. and Wolgemuth, C. (2012). The unique paradigm of spirochete motility and chemotaxis. Annual Review of Microbiology 66, 349370.Google Scholar
Craine, N. G., Randolph, S. E. and Nuttall, P. A. (1995). Seasonal variation in the role of grey squirrels as hosts of Ixodes ricinus, the tick vector of the Lyme disease spirochaete, in a British woodland. Folia Parasitologica 42, 7380.Google Scholar
Daniels, T. J. and Fish, D. (1990). Spatial distribution and dispersal of unfed larval Ixodes dammini (Acari, Ixodidae) in southern New York. Environmental Entomology 19, 10291033.CrossRefGoogle Scholar
Derdakova, M., Dudioak, V., Brei, B., Brownstein, J. S., Schwartz, I. and Fish, D. (2004). Interaction and transmission of two Borrelia burgdorferi sensu stricto strains in a tick-rodent maintenance system. Applied and Environmental Microbiology 70, 67836788.Google Scholar
Devevey, G. and Brisson, D. (2012). The effect of spatial heterogeneity on the aggregation of ticks on white-footed mice. Parasitology 139, 915925.CrossRefGoogle ScholarPubMed
Donahue, J. G., Piesman, J. and Spielman, A. (1987). Reservoir competence of white-footed mice for Lyme disease spirochetes. American Journal of Tropical Medicine and Hygiene 36, 9296.Google Scholar
Gatewood, A. G., Liebman, K. A., Vourc'h, G., Bunikis, J., Hamer, S. A., Cortinas, R., Melton, F., Cislo, P., Kitron, U., Tsao, J., Barbour, A. G., Fish, D. and Diuk-Wasser, M. A. (2009). Climate and tick seasonality are predictors of Borrelia burgdorferi genotype distribution. Applied and Environmental Microbiology 75, 24762483.CrossRefGoogle ScholarPubMed
Gern, L. and Humair, P. F. (1998). Natural history of Borrelia burgdorferi sensu lato. Wiener Klinische Wochenschrift 110, 856858.Google Scholar
Gern, L. and Humair, P.-F. (2002). Ecology of Borrelia burgdorferi sensu lato in Europe. In Lyme Borreliosis: Biology, Epidemiology, and Control (ed. Gray, J. S., Kahl, O., Lane, R. S. and Stanek, G.), pp. 149174. CABI Publishing, Wallingford, Oxfordshire, UK.Google Scholar
Gern, L. and Rais, O. (1996). Efficient transmission of Borrelia burgdorferi between cofeeding Ixodes ricinus ticks (Acari: Ixodidae). Journal of Medical Entomology 33, 189192.CrossRefGoogle ScholarPubMed
Gern, L., Schaible, U. E. and Simon, M. M. (1993). Mode of inoculation of the Lyme disease agent Borrelia burgdorferi influences infection and immune responses in inbred strains of mice. Journal of Infectious Diseases 167, 971975.Google Scholar
Gern, L., Siegenthaler, M., Hu, C. M., Leuba-Garcia, S., Humair, P. F. and Moret, J. (1994). Borrelia burgdorferi in rodents (Apodemus flavicollis and A. sylvaticus): duration and enhancement of infectivity for Ixodes ricinus ticks. European Journal of Epidemiology 10, 7580.Google Scholar
Gern, L., Estrada-Pena, A., Frandsen, F., Gray, J. S., Jaenson, T. G. T., Jongejan, F., Kahl, O., Korenberg, E., Mehl, R. and Nuttall, P. A. (1998). European reservoir hosts of Borrelia burgdorferi sensu lato. Zentralblatt Fur Bakteriologie – International Journal of Medical Microbiology Virology Parasitology and Infectious Diseases 287, 196204.Google ScholarPubMed
Gray, J. S., Kirstein, F., Robertson, J. N., Stein, J. and Kahl, O. (1999). Borrelia burgdorferi sensu lato in Ixodes ricinus ticks and rodents in a recreational park in south-western Ireland. Experimental and Applied Acarology 23, 717729.Google Scholar
Guo, X., Booth, C., Paley, M., Wang, X., DePonte, K., Fikrig, E., Narasimhan, S. and Montgomery, R. (2009). Inhibition of neutrophil function by two tick salivary proteins. Infection and Immunity 77, 23202329.CrossRefGoogle ScholarPubMed
Hanincova, K., Schafer, S. M., Etti, S., Sewell, H. S., Taragelova, V., Ziak, D., Labuda, M. and Kurtenbach, K. (2003 a). Association of Borrelia afzelii with rodents in Europe. Parasitology 126, 1120.Google Scholar
Hanincova, K., Taragelova, V., Koci, J., Schafer, S. M., Hails, R., Ullmann, A. J., Piesman, J., Labuda, M. and Kurtenbach, K. (2003 b). Association of Borrelia garinii and B. valaisiana with songbirds in Slovakia. Applied and Environmental Microbiology 69, 28252830.Google Scholar
Hanincova, K., Ogden, N. H., Diuk-Wasser, M., Pappas, C. J., Iyer, R., Fish, D., Schwartz, I. and Kurtenbach, K. (2008). Fitness variation of Borrelia burgdorferi sensu stricto strains in mice. Applied and Environmental Microbiology 74, 153157.Google Scholar
Harrison, A. and Bennett, N. (2012). The importance of the aggregation of ticks on small mammal hosts for the establishment and persistence of tick-borne pathogens: an investigation using the R(0) model. Parasitology 139, 16051613.Google Scholar
Harrison, A., Montgomery, W. I. and Bown, K. J. (2011). Investigating the persistence of tick-borne pathogens via the R-0 model. Parasitology 138, 896905.CrossRefGoogle Scholar
Hartemink, N. A., Randolph, S. E., Davis, S. A. and Heesterbeek, J. A. P. (2008). The basic reproduction number for complex disease systems: defining R-0 for tick-borne infections. American Naturalist 171, 743754.CrossRefGoogle ScholarPubMed
Hasle, G. (2013). Transport of ixodid ticks and tick-borne pathogens by migratory birds. Frontiers in Cellular and Infection Microbiology 3, 48.Google Scholar
Herrmann, C., Gern, L. and Voordouw, M. (2013). Species co-occurrence patterns among Lyme borreliosis pathogens in the tick vector Ixodes ricinus . Applied and Environmental Microbiology, 79, 72737280.CrossRefGoogle ScholarPubMed
Higgs, S., Schneider, B. S., Vanlandingham, D. L., Klingler, K. A. and Gould, E. A. (2005). Nonviremic transmission of West Nile virus. Proceedings of the National Academy of Sciences of the United States of America 102, 88718874.Google Scholar
Hu, C. M., Cheminade, Y., Perret, J. L., Weynants, V., Lobet, Y. and Gern, L. (2003). Early detection of Borrelia burgdorferi sensu lato infection in Balb/c mice by co-feeding Ixodes ricinus ticks. International Journal of Medical Microbiology 293, 421426.Google Scholar
Huegli, D., Hu, C. M., Humair, P. F., Wilske, B. and Gern, L. (2002). Apodemus species mice are reservoir hosts of Borrelia garinii OspA serotype 4 in Switzerland. Journal of Clinical Microbiology 40, 47354737.CrossRefGoogle ScholarPubMed
Hughes, V. L. and Randolph, S. E. (2001). Testosterone depresses innate and acquired resistance to ticks in natural rodent hosts: a force for aggregated distributions of parasites. The Journal of Parasitology 87, 4954.Google Scholar
Humair, P. F. and Gern, L. (1998). Relationship between Borrelia burgdorferi sensu lato species, red squirrels (Sciurus vulgaris) and Ixodes ricinus in enzootic areas in Switzerland. Acta Tropica 69(3), 213227.Google Scholar
Humair, P. F. and Gern, L. (2000). The wild hidden face of Lyme borreliosis in Europe. Microbes and Infection 2, 915922.Google Scholar
Humair, P. F., Péter, O., Wallich, R. and Gern, L. (1995). Strain variation of Lyme disease spirochetes isolated from Ixodes ricinus ticks and rodents collected in two endemic areas in Switzerland. Journal of Medical Entomology 32, 433438.Google Scholar
Humair, P. F., Postic, D., Wallich, R. and Gern, L. (1998). An avian reservoir (Turdus merula) of the Lyme borreliosis spirochetes. Zentralblatt Fur Bakteriologie – International Journal of Medical Microbiology Virology Parasitology and Infectious Diseases 287, 521538.Google Scholar
Jaenson, T. G. T. and Talleklint, L. (1992). Incompetence of roe deer as reservoirs of the Lyme borreliosis spirochete. Journal of Medical Entomology 29, 813817.Google Scholar
Johnson, R. C., Kodner, C. and Russell, M. (1986 a). Active immunization of hamsters against experimental infection with Borrelia burgdorferi . Infection and Immunity 54, 897898.Google Scholar
Johnson, R. C., Kodner, C. and Russell, M. (1986 b). Passive immunization of hamsters against experimental infection with the Lyme disease spirochete. Infection and Immunity 53, 713714.CrossRefGoogle ScholarPubMed
Jones, L. D., Davies, C. R., Steele, G. M. and Nuttall, P. A. (1987). A novel mode of arbovirus transmission involving a nonviremic host. Science 237, 775777.CrossRefGoogle ScholarPubMed
Keesing, F., Brunner, J., Duerr, S., Killilea, M., LoGiudice, K., Schmidt, K., Vuong, H. and Ostfeld, R. S. (2009). Hosts as ecological traps for the vector of Lyme disease. Proceedings of the Royal Society Biological Sciences Series B 267, 39113919.Google Scholar
Kiffner, C., Lodige, C., Alings, M., Vor, T. and Ruhe, F. (2011). Attachment site selection of ticks on roe deer, Capreolus capreolus . Experimental and Applied Acarology 53, 7994.Google Scholar
Kimura, K., Isogai, E., Isogai, H., Kamewaka, Y., Nishikawa, T., Ishii, N. and Fujii, N. (1995). Detection of Lyme disease spirochetes in the skin of naturally infected wild sika deer (Cervus nippon yesoensis) by PCR. Applied and Environmental Microbiology 61, 16411642.Google Scholar
Kjelland, V., Ytrehus, B., Vikoren, T., Stuen, S., Skarpaas, T., Vikørren, T. and Slettan, A. (2011). Borrelia burgdorferi sensu lato detected in skin of Norwegian mountain hares (Lepus timidus) without signs of dissemination. Journal of Wildlife Diseases 47, 293299.Google Scholar
Kocan, K. and de la Fuente, J. (2003). Co-feeding studies of ticks infected with Anaplasma marginale . Veterinary Parasitology 112, 295305.Google Scholar
Kurtenbach, K., Peacey, M., Rijpkema, S. G. T., Hoodless, A. N., Nuttall, P. A. and Randolph, S. E. (1998 a). Differential transmission of the genospecies of Borrelia burgdorferi sensu lato by game birds and small rodents in England. Applied and Environmental Microbiology 64, 11691174.Google Scholar
Kurtenbach, K., Sewell, H. S., Ogden, N. H., Randolph, S. E. and Nuttall, P. A. (1998 b). Serum complement sensitivity as a key factor in Lyme disease ecology. Infection and Immunity 66, 12481251.Google Scholar
Kurtenbach, K., De Michelis, S., Sewell, H. S., Etti, S., Schafer, S. M., Hails, R., Collares-Pereira, M., Santos-Reis, M., Hanincova, K., Labuda, M., Bormane, A. and Donaghy, M. (2001). Distinct combinations of Borrelia burgdorferi sensu lato genospecies found in individual questing ticks from Europe. Applied and Environmental Microbiology 67, 49264929.Google Scholar
Kurtenbach, K., De Michelis, S., Etti, S., Schafer, S. M., Sewell, H. S., Brade, V. and Kraiczy, P. (2002 a). Host association of Borrelia burgdorferi sensu lato – the key role of host complement. Trends in Microbiology 10, 7479.Google Scholar
Kurtenbach, K., Schafer, S. M., Sewell, H. S., Peacey, M., Hoodless, A., Nuttall, P. A. and Randolph, S. E. (2002 b). Differential survival of Lyme borreliosis spirochetes in ticks that feed on birds. Infection and Immunity 70, 58935895.CrossRefGoogle ScholarPubMed
Kurtenbach, K., Hanincova, K., Tsao, J. I., Margos, G., Fish, D. and Ogden, N. H. (2006). Fundamental processes in the evolutionary ecology of Lyme borreliosis. Nature Reviews Microbiology 4, 660669.Google Scholar
Kuthejlová, M., Kopecky, J., Stepanova, G., Macela, A., Kopecký, J. and Stepánová, G. (2001). Tick salivary gland extract inhibits killing of Borrelia afzelii spirochetes by mouse macrophages. Infection and Immunity 69, 575578.Google Scholar
Labuda, M., Kozuch, O., Eleckova, E., Williams, T., Nuttall, P. A., Elecková, E., Zuffová, E. and Sabó, A. (1993 a). Non-viraemic transmission of tick-borne encephalitis virus: a mechanism for arbovirus survival in nature. Experientia 49, 802805.Google Scholar
Labuda, M., Williams, T., Danielova, V., Jones, L. D. and Nuttall, P. A. (1993 b). Efficient transmission of tick-borne encephalitis virus between cofeeding ticks. Journal of Medical Entomology 30, 295299.CrossRefGoogle ScholarPubMed
Labuda, M., Williams, T., Jones, L. D. and Nuttall, P. A. (1993 c). Enhancement of tick-borne encephalitis virus transmission by tick salivary gland extracts. Medical and Veterinary Entomology 7, 193196.Google Scholar
Labuda, M., Zuffova, E., Kozuch, O., Fuchsberger, N., Austyn, J. M., Lysy, J. and Nuttall, P. A. (1996). Importance of localized skin infection in tick-borne encephalitis virus transmission. Virology 219, 357366.Google Scholar
Labuda, M., Kozuch, O., Zuffova, E., Eleckova, E., Hails, R. S. and Nuttall, P. A. (1997). Tick-borne encephalitis virus transmission between ticks cofeeding on specific immune natural rodent hosts. Virology 235, 138143.Google Scholar
Levin, M. L. and Fish, D. (2000). Immunity reduces reservoir host competence of Peromyscus leucopus for Ehrlichia phagocytophila . Infection and Immunity 68, 15141518.Google Scholar
Lindsay, L. R., Barker, I. K., Surgeoner, G. A., McEwen, S. A. and Campbell, G. D. (1997). Duration of Borrelia burgdorferi infectivity in white-footed mice for the tick vector Ixodes scapularis under laboratory and field conditions in Ontario. Journal of Wildlife Diseases 33, 766775.CrossRefGoogle ScholarPubMed
MacQueen, D., Lubelczyk, C., Elias, S., Cahill, B., Mathers, A., Lacombe, E., Rand, P. and Smith, R. (2012). Genotypic diversity of an emergent population of Borrelia burgdorferi at a coastal Maine island recently colonized by Ixodes scapularis . Vector Borne and Zoonotic Diseases 12, 456461.Google Scholar
Matuschka, F. R., Heiler, M., Eiffert, H., Fischer, P., Lotter, H. and Spielman, A. (1993). Diversionary role of hoofed game in the transmission of Lyme disease spirochetes. American Journal of Tropical Medicine and Hygiene 48, 693699.CrossRefGoogle ScholarPubMed
Mead, D. G., Ramberg, F. B., Besselsen, D. G. and Mare, C. J. (2000). Transmission of vesicular stomatitis virus from infected to noninfected black flies co-feeding on nonviremic deer mice. Science 287, 485487 Google Scholar
Mejri, N., Rutti, B. and Brossard, M. (2002). Immunosuppressive effects of Ixodes ricinus tick saliva or salivary gland extracts on innate and acquired immune response of BALB/c mice. Parasitology Research 88, 192197.Google Scholar
Montgomery, R. R., Nathanson, M. H. and Malawista, S. E. (1993). The fate of Borrelia burgdorferi, the agent for Lyme disease, in mouse macrophages. Destruction, survival, recovery. The Journal of Immunology 150, 909915.CrossRefGoogle ScholarPubMed
Morán Cadenas, F. M., Rais, O., Humair, P. F., Douet, V., Moret, J. and Gern, L. (2007). Identification of host bloodmeal source and Borrelia burgdorferi sensu lato in field-collected Ixodes ricinus ticks in Chaumont (Switzerland). Journal of Medical Entomology 44, 11091117.Google Scholar
Nuttall, P. A. (1999). Pathogen-tick-host interactions: Borrelia burgdorferi and TBE virus. Zentralblatt für Bakteriologie 289, 492505.Google Scholar
Nuttall, P. A. and Labuda, M. (2003). Dynamics of infection in tick vectors and at the tick-host interface. Flaviviruses: Pathogenesis and Immunity 60, 233272.Google Scholar
Nuttall, P. A. and Labuda, M. (2004). Tick-host interactions: saliva-activated transmission. Parasitology 129, S177S189.Google Scholar
Ogden, N. H., Nuttall, P. A. and Randolph, S. E. (1997). Natural Lyme disease cycles maintained via sheep by cofeeding ticks. Parasitology 115, 591599.Google Scholar
Ogden, N. H., Hailes, R. S. and Nuttall, P. A. (1998 a). Interstadial variation in the attachment sites of Ixodes ricinus ticks on sheep. Experimental and Applied Acarology 22, 227232.Google Scholar
Ogden, N. H., Kurtenbach, K. and Nuttall, P. A. (1998 b). Interstadial and infestation level-dependent variation in the transmission efficiency of Borrelia burgdorferi from mice to Ixodes ricinus ticks. Experimental and Applied Acarology 22, 367372.CrossRefGoogle ScholarPubMed
Ogden, N. H., Bigras-Poulin, M., O'Callaghan, C. J., Barker, I. K., Kurtenbach, K., Lindsay, L. R. and Charron, D. (2007). Vector seasonality, host infection dynamics and fitness of pathogens transmitted by the tick Ixodes scapularis . Parasitology 134, 209227.CrossRefGoogle ScholarPubMed
Papatheodorou, V. and Brossard, M. (1987). C-3 levels in the sera of rabbits infested and reinfested with Ixodes ricinus L and in midguts of fed ticks. Experimental and Applied Acarology 3, 5359.Google Scholar
Patrican, L. A. (1997). Acquisition of Lyme disease spirochetes by cofeeding Ixodes scapularis ticks. The American journal of tropical medicine and hygiene 57, 589593.CrossRefGoogle ScholarPubMed
Pechová, J., Stepanova, G., Kovar, L., Kopecky, J., Kovár, L. and Kopecký, J. (2002). Tick salivary gland extract-activated transmission of Borrelia afzelii spirochaetes. Folia Parasitologica 49, 153159.Google Scholar
Pérez, D., Kneubühler, Y., Rais, O., Jouda, F. and Gern, L. (2011). Borrelia afzelii ospC genotype diversity in Ixodes ricinus questing ticks and ticks from rodents in two Lyme borreliosis endemic areas: contribution of co-feeding ticks. Ticks and Tick-borne Diseases 2, 137142.Google Scholar
Perkins, S. E., Cattadori, I. M., Tagliapietra, V., Rizzoli, A. P. and Hudson, P. J. (2003). Empirical evidence for key hosts in persistence of a tick-borne disease. International Journal for Parasitology 33, 909917.Google Scholar
Pichon, B., Gilot, B. and Perez-Eid, C. (2000). Detection of spirochaetes of Borrelia burgdorferi complex in the skin of cervids by PCR and culture. European Journal of Epidemiology 16, 869873.Google ScholarPubMed
Pichon, B., Egan, D., Rogers, M. and Gray, J. (2003). Detection and identification of pathogens and host DNA in unfed host-seeking Ixodes ricinus L. (Acari: Ixodidae). Journal of Medical Entomology 40, 723731.Google Scholar
Pichon, B., Rogers, M., Egan, D. and Gray, J. (2005). Blood-meal analysis for the identification of reservoir hosts of tick-borne pathogens in Ireland. Vector-Borne and Zoonotic Diseases 5, 172180.Google Scholar
Piesman, J. and Happ, C. M. (2001). The efficacy of co-feeding as a means of maintaining Borrelia burgdorferi: a North American model system. Journal of Vector Ecology 26, 216220.Google Scholar
Piesman, J., Dolan, M. C., Happ, C. M., Luft, B. J., Rooney, S. E., Mather, T. N. and Golde, W. T. (1997). Duration of immunity to reinfection with tick-transmitted Borrelia burgdorferi in naturally infected mice. Infection and Immunity 65, 40434047.CrossRefGoogle ScholarPubMed
Qiu, W. G., Bosler, E. M., Campbell, J. R., Ugine, G. D., Wang, I. N., Luft, B. J. and Dykhuizen, D. E. (1997). A population genetic study of Borrelia burgdorferi sensu stricto from eastern Long Island, New York, suggested frequency-dependent selection, gene flow and host adaptation. Hereditas 127, 203216.Google Scholar
Qiu, W. G., Dykhuizen, D. E., Acosta, M. S. and Luft, B. J. (2002). Geographic uniformity of the Lyme disease spirochete (Borrelia burgdorferi) and its shared history with tick vector (Ixodes scapularis) in the northeastern United States. Genetics 160, 833849.Google Scholar
Raberg, L. (2012). Infection intensity and infectivity of the tick-borne pathogen Borrelia afzelii . Journal of Evolutionary Biology 25, 14481453.Google Scholar
Ramamoorthi, N., Narasimhan, S., Pal, U., Bao, F. K., Yang, X. F. F., Fish, D., Anguita, J., Norgard, M. V., Kantor, F. S., Anderson, J. F., Koski, R. A. and Fikrig, E. (2005). The Lyme disease agent exploits a tick protein to infect the mammalian host. Nature 436, 573577.Google Scholar
Randolph, S. E. (1975). Patterns of distribution of the tick Ixodes trianguliceps Birula on its host. Journal of Animal Ecology 44, 451474.CrossRefGoogle Scholar
Randolph, S. E. (1998). Ticks are not insects: consequences of contrasting vector biology for transmission potential. Parasitology Today 14, 186192.Google Scholar
Randolph, S. E. (2009). Tick-borne disease systems emerge from the shadows: the beauty lies in molecular detail, the message in epidemiology. Parasitology 136, 14031413.Google Scholar
Randolph, S. E. (2011). Transmission of tick-borne pathogens between co-feeding ticks: Milan Labuda's enduring paradigm. Ticks and Tick-borne Diseases 2, 179182.Google Scholar
Randolph, S. E. and Gern, L. (2003). Co-feeding transmission and its contribution to the perpetuation of the Lyme disease spirochete Borrelia afzelii . Emerging Infectious Diseases 9, 893894.CrossRefGoogle Scholar
Randolph, S. E. and Rogers, D. J. (2000). Fragle transmission cycles of tick-borne encephalitis virus may be disrupted by predicted climate change. Proceedings of the Royal Society Biological Sciences Series B 267, 17411744.Google Scholar
Randolph, S. E. and Sumilo, D. (2007). Tick-borne encephalitis in Europe: dynamics of changing risk. In Emerging Pests and Vector-borne Diseases in Europe (ed. Takken, W. and Knols, B. G. J.), pp. 187206. Wageningen Academic Publishers, Wageningen.Google Scholar
Randolph, S. E., Gern, L. and Nuttall, P. A. (1996). Co-feeding ticks: epidemiological significance for tick-borne pathogen transmission. Parasitology Today 12, 472479.Google Scholar
Randolph, S. E., Miklisova, D., Lysy, J., Rogers, D. J. and Labuda, M. (1999). Incidence from coincidence: patterns of tick infestations on rodents facilitate transmission of tick-borne encephalitis virus. Parasitology 118, 177186.Google Scholar
Rechav, Y. and Nuttall, P. A. (2000). The effect of male ticks on the feeding performance of immature stages of Rhipicephalus sanguineus and Amblyomma americanum (Acari: Ixodidae). Experimental and Applied Acarology 24, 569578.Google Scholar
Ribeiro, J. M. C. (1987). Ixodes dammini – salivary anti-complement activity. Experimental Parasitology 64, 347353.Google Scholar
Ribeiro, J. M. C. (1995). How ticks make a living. Parasitology Today 11, 9193.Google Scholar
Ribeiro, J. M. C. and Spielman, A. (1986). Ixodes dammini – salivary anaphylatoxin inactivating activity. Experimental Parasitology 62, 292297.Google Scholar
Ribeiro, J. M. C., Weis, J. J. and Telford, S. R. (1990). Saliva of the tick Ixodes dammini inhibits neutrophil function. Experimental Parasitology 70, 382388.Google Scholar
Richter, D., Allgower, R. and Matuschka, F. R. (2002). Co-feeding transmission and its contribution to the perpetuation of the Lyme disease spirochete Borrelia afzelii . Emerging Infectious Diseases 8, 14211425.Google Scholar
Richter, D., Allgower, R. and Matuschka, F. R. (2003). Co-feeding transmission and its contribution to the perpetuation of the Lyme disease spirochete Borrelia afzelii . Emerging Infectious Diseases 9, 895896.Google Scholar
Richter, D., Debski, A., Hubalek, Z. and Matuschka, F. R. (2012). Absence of Lyme disease spirochetes in larval Ixodes ricinus ticks. Vector-Borne and Zoonotic Diseases 12, 2127.Google Scholar
Rollend, L., Fish, D. and Childs, J. E. (2013). Transovarial transmission of Borrelia spirochetes by Ixodes scapularis: a summary of the literature and recent observations. Ticks and Tick-borne Diseases 4, 4651.CrossRefGoogle ScholarPubMed
Rudolf, I., Hubalek, Z. and Hubálek, Z. (2003). Effect of the salivary gland and midgut extracts from Ixodes ricinus and Dermacentor reticulatus (Acari: Ixodidae) on the growth of Borrelia garinii in vitro. Folia Parasitologica 50, 159160.Google Scholar
Rudolf, I., Sikutova, S., Kopecky, J. and Hubalek, Z. (2010). Salivary gland extract from engorged Ixodes ricinus (Acari: Ixodidae) stimulates in vitro growth of Borrelia burgdorferi sensu lato. Journal of Basic Microbiology 50, 294298.Google Scholar
Sato, Y. and Nakao, M. (1997). Transmission of the Lyme disease spirochete, Borrelia garinii, between infected and uninfected immature Ixodes persulcatus during cofeeding on mice. Journal of Parasitology 83, 547550.Google Scholar
Scheckelhoff, M., Telford, S., Wesley, M. and Hu, L. (2007). Borrelia burgdorferi intercepts host hormonal signals to regulate expression of outer surface protein A. Proceedings of the National Academy of Sciences of the United States of America 104, 72477252.CrossRefGoogle ScholarPubMed
Schmidt, K. A., Ostfeld, R. S. and Schauber, E. M. (1999). Infestation of Peromyscus leucopus and Tamias striatus by Ixodes scapularis (Acari: Ixodidae) in relation to the abundance of hosts and parasites. Journal of Medical Entomology 36, 749757.Google Scholar
Scott, M. C., Harmon, J. R., Tsao, J. I., Jones, C. J. and Hickling, G. J. (2012). Reverse line blot probe design and polymerase chain reaction optimization for bloodmeal analysis of ticks from the eastern United States. Journal of Medical Entomology 49, 697709.Google Scholar
Shaw, M., Keesing, F., McGrail, R. and Ostfeld, R. (2003). Factors influencing the distribution of larval blacklegged ticks on rodent hosts. The American Journal of Tropical Medicine and Hygiene 68, 447452.Google Scholar
Shih, C. M., Spielman, A., Pollack, R. J. and Telford, S. R. (1992). Delayed dissemination of Lyme disease spirochetes from the site of deposition in the skin of mice. The Journal of infectious diseases 166, 827831.Google Scholar
Shih, C. M., Chao, L. L. and Yu, C. P. (2002). Chemotactic migration of the Lyme disease spirochete (Borrelia burgdorferi) to salivary gland extracts of vector ticks. American Journal of Tropical Medicine and Hygiene 66, 616621.Google Scholar
Sonenshine, D. E. (2004). Pheromones and other semiochemicals of ticks and their use in tick control. Parasitology 129(Suppl), S405425.Google Scholar
Stearns, S. C. (1992). The Evolution of Life-Histories. Oxford University Press, Oxford.Google Scholar
Steele, G. M. and Randolph, S. E. (1985). An experimental evaluation of conventional control measures against the sheep tick, Ixodes ricinus (L.) (Acari, Ixodidae). I. A unimodal seasonal activity pattern. Bulletin of Entomological Research 75, 489499.Google Scholar
Swanson, K. I. and Norris, D. E. (2008). Presence of multiple variants of Borrelia burgdorferi in the natural reservoir Peromyscus leucopus throughout a transmission season. Vector-Borne and Zoonotic Diseases 8, 397405.Google Scholar
Taragel'ová, V., Koci, J., Hanincova, K., Kurtenbach, K., Derdakova, M., Ogden, N. H., Hanincová, K., Derdáková, M., Literák, I., Kocianová, E. and Labuda, M. (2008). Blackbirds and song thrushes constitute a key reservoir of Borrelia garinii, the causative agent of borreliosis in Central Europe. Applied and Environmental Microbiology 74, 12891293.Google Scholar
Telford, S. R., Mather, T. N., Moore, S. I., Wilson, M. L. and Spielman, A. (1988). Incompetence of deer as reservoirs of the Lyme-disease spirochete. American Journal of Tropical Medicine and Hygiene 39, 105109.Google Scholar
Tonetti, N. and Gern, L. (2011). Dynamic of host-tick-host transmission of Borrelia afzelii osp C groups. In Seventh Ticks and Tick-borne Pathogens International Conference, Zaragoza, Spain.Google Scholar
Tsao, J. (2009). Reviewing molecular adaptations of Lyme borreliosis spirochetes in the context of reproductive fitness in natural transmission cycles. Veterinary Research (Paris) 40, 36.Google Scholar
Wang, G., Ojaimi, C., Iyer, R., Saksenberg, V., McClain, S. A., Wormser, G. P. and Schwartz, I. (2001 a). Impact of genotypic variation of Borrelia burgdorferi sensu stricto on kinetics of dissemination and severity of disease in C3H/HeJ mice. Infection and Immunity 69, 43034312.Google Scholar
Wang, H., Paesen, G. C., Nuttall, P. A. and Barbour, A. G. (1998). Male ticks help their mates to feed. Nature 391, 753754.Google Scholar
Wang, H., Hails, R. S., Cui, W. W. and Nuttall, P. A. (2001 b). Feeding aggregation of the tick Rhipicephalus appendiculatus (Ixodidae): benefits and costs in the contest with host responses. Parasitology 123(Pt 5), 447453.Google Scholar
Wang, I. N., Dykhuizen, D. E., Qiu, W., Dunn, J. J., Bosler, E. M. and Luft, B. J. (1999). Genetic diversity of ospC in a local population of Borrelia burgdorferi sensu stricto. Genetics 151, 1530.CrossRefGoogle Scholar
Woolhouse, M. E., Dye, C., Smith, T., Etard, J. F., Charlwood, J. D., Garnett, G. P., Hagan, P., Hii, J. L., Ndhlovu, P. D., Quinnell, R. J., Watts, C. H., Chandiwana, S. K. and Anderson, R. M. (1997). Heterogeneities in the transmission of infectious agents: implications for the design of control programs. Proceedings of the National Academy of Sciences of the United States of America 94, 338342.Google Scholar
Zeidner, N. S., Gern, L., Piesman, J., Schneider, B. S. and Nuncio, M. S. (2002). Coinoculation of Borrelia spp. with tick salivary gland lysate enhances spirochete load in mice and is tick species-specific. The Journal of Parasitology 88, 12761278.Google Scholar
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Fig. 1. The diagram shows (A) co-feeding (nymph-to-larva) transmission and (B) systemic (host-to-larva) transmission of Borrelia spirochaetes in a rodent reservoir host. Co-feeding transmission can occur when ticks feed in close spatial and temporal proximity on the same host. Larva 2 does not acquire spirochaetes via co-feeding transmission because it is too far away from the infected nymph. Systemic transmission occurs once the spirochaetes have had enough time to disseminate to all the relevant tissues of the reservoir host, which usually takes about 2 weeks. Under systemic transmission, larvae can acquire spirochaetes by attaching anywhere on the infected mouse.