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Applied and Environmental Microbiology, February 1999, p. 707-711, Vol. 65, No. 2
0099-2240/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Characteristics of Garden Dormice That Contribute
to Their Capacity as Reservoirs for Lyme Disease Spirochetes
Franz-Rainer
Matuschka,1,2
Rainer
Allgöwer,1
Andrew
Spielman,2 and
Dania
Richter1,2,*
Institut für Pathologie, Charité,
Medizinische Fakultät der Humboldt-Universität zu
Berlin, 12249 Berlin, Germany,1 and
Department of Immunology and Infectious Diseases, Harvard
School of Public Health, Boston, Massachusetts
021152
Received 20 July 1998/Accepted 23 November 1998
 |
ABSTRACT |
To describe the contribution of garden dormice to the epizootiology
of Lyme disease, we compared their reservoir capacity for these
pathogens to that of other sympatric hosts. Garden dormice are trapped
most abundantly during early spring and again during midsummer, when
their offspring forage. They are closely associated with moist forests.
Garden dormice serve as hosts to nymphal ticks far more frequently than
do other small mammals. Spirochetal infection is most prevalent in
dormice, and many more larval ticks acquire infection in the course of
feeding on these than on other rodents in the study site. Mature
dormice appear to contribute more infections to the vector population
than juveniles do. Replete larval ticks generally detach while their
dormouse hosts remain within their nests. The population of garden
dormice contributes five- to sevenfold more infections to the vector
population than the mouse population does. Their competence, nymphal
feeding density, and preference for a tick-permissive habitat combine
to favor garden dormice over other putative reservoir hosts of Lyme
disease spirochetes.
| |
INTRODUCTION |
Although mice of the species
Apodemus flavicollis and Apodemus sylvaticus
appear to be the main reservoir hosts for Lyme disease spirochetes
(Borrelia burgdorferi sensu lato, hereafter termed spirochetes) in much of central Europe (3), edible dormice, Glis glis, may contribute at least twice as many such
spirochetal infections to the local population of Ixodes
ricinus vector ticks (5). This differential capacity of
edible dormice as reservoirs for the agent of Lyme disease derives from
the numerous nymphal ticks that feed on them and their longer life
spans. A larger tick load implies that infectivity for vector ticks
begins earlier in life, and greater longevity implies a relatively
extended duration of infectivity. The prevalence of infection in edible
dormice, therefore, greatly exceeds that in mice.
Garden dormice, Eliomys quercinus, are about as long-lived
as edible dormice are (10, 11), and the similarity in their sizes suggests that both may be parasitized by similar densities of
nymphal ticks. These animals differ in an additional potentially reservoir-relevant behavioral trait. Edible dormice inhabit relatively dry forests that tend to be mature, whereas garden dormice become abundant where the forest is more humid and transitional; these kinds
of dormice rarely coexist (10, 13). Because vector ticks tend to be most abundant in such relatively humid sites, the capacity of garden dormice as hosts for the Lyme disease spirochete may correspondingly exceed that of edible dormice. The epizootiological significance of the correlation between the niche of reservoir and
vector hosts, however, has not systematically been examined.
It may be that the capacity of garden dormice as reservoir hosts for
the Lyme disease spirochete is far greater than that of other small
mammals in sites in which vector ticks most readily thrive. To describe
the characteristics of garden dormice that promote their contribution
of spirochetal infections to the vector population, we related the
epizootiology of these spirochetes transmitted among garden dormice to
that in mice and other small mammals present in the same site.
(Portions of this research were conducted in partial fulfillment of the
requirements for a doctoral degree from the Humboldt-Universität zu Berlin, Berlin, Germany.)
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MATERIALS AND METHODS |
Description of study site.
Our study site was located in the
Petite Carmarque, a forested region in France, near the German and
Swiss borders at an altitude of 240 m above sea level and within
the flood plain of the Rhein River. This 224-ha region had been
excavated extensively and otherwise exploited during the 1800s and
early 1900s. Segments began to revert to forest after 1908. A key
bastion of the Maginot line had been located there. The Petite
Carmarque was declared a nature preserve in 1982. The trees covering
the study site itself appear to be between 15 and 30 years of age and
include oak, alder, and ash; dense brush covers the forest floor.
Trapping method.
Small mammals were captured in live traps
(Longworth Scientific Instruments, Abingdon, United Kingdom) baited
with apple, grain, and cotton. A total of 60 traps were placed in the
site for four successive nights each month from April through October 1995. Traps were spaced 8 to 10 m apart in linear arrays
straddling the ecotone on either side. Captured small mammals were
taken to the laboratory, where they were weighed and identified. They were caged over water until all naturally attached ticks had detached. The water was inspected twice daily, and ticks were promptly removed, counted, and identified. After subsequent xenodiagnosis, the animals were released at the point of capture. Ticks were collected once a
month at the site by means of a flannel flag. They were confined in
screened vials and stored at 15 ± 1°C until they were
identified as to stage and species and examined for spirochetes.
Ticks used for xenodiagnosis were derived from laboratory-bred adult
I. ricinus ticks. Subadult and adult ticks were reared by
feeding on spirochete-free jirds and on rabbits, respectively. These
ticks were in their third generation of continuous laboratory rearing
and had never been exposed to infected hosts. A portion of each larval
cohort was routinely examined for the presence of spirochetes by
dark-field microscopy and also by feeding them on mice.
For xenodiagnosis (
7) and studies on time of detachment,
about 50 laboratory-reared larval ticks were brushed onto each
dormouse
at 1800 h. Infested hosts were enclosed in wire mesh
tubes that
were wrapped in absorbent paper for 2 to 3 h. The dormice
were
subsequently removed and caged over water; the water was
inspected
every 2 h, and replete ticks were removed. The photophase
began at
0800 h, and the scotophase began at 2200
h.
After detachment, engorged ticks (both laboratory reared and those
naturally attached) were enclosed in screened vials and
kept at 20 ± 2°C in sealed desiccator jars over supersaturated
MgSO
4 under a light-dark (16 h-8 h) regime. Molted ticks
remained
in the original vials until they were examined for the
presence
of
spirochetes.
Field-collected questing ticks as well as molted ticks that had
engorged on small mammals were dissected, and their midguts
were
examined for spirochetal infection by dark-field microscopy
(
4).
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RESULTS |
To help describe the natural history of the garden dormouse in our
study site, we collected these animals by using arrays of traps
deployed from April through October. Dormice entered these traps most
frequently in May (Fig. 1). We used
weight as an indicator of age of these dormice, but solely during late
summer. About a third of these animals weighed less than <50 g in May, presumably because they had not yet recovered from hibernation. Indeed,
the pelage of these underweight dormice confirmed their maturity. The
trapping frequency of mature dormice subsequently declined, reflecting
a change in activity rather than in abundance. The first immature
dormice were captured in August; these animals weighed <50 g and were
covered with grey juvenile fur. By October, virtually all dormice
weighed at least 50 g. We conclude that garden dormice move most
abundantly over the forest floor in April and May and again in
midsummer, when the offspring of the year begin to forage.
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FIG. 1.
Seasonal distribution of garden dormice, E. quercinus, that weigh more than 50 g and those that weigh
less.
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To evaluate the contribution of various small mammals as hosts for Lyme
disease spirochetes in the Petite Carmarque study site, we determined
the relative densities of the small mammals endemic there and the
densities of subadult vector ticks feeding on them. Of the five kinds
of small mammals that were captured, garden dormice and wood mice,
A. sylvaticus, entered these traps most frequently (Table
1). Subadult I. ricinus ticks
were the only kind of ticks parasitizing these animals. Although larvae infested about as many dormice as they did other small mammals, the
densities of larvae feeding on dormice and mice were greater than those
on bank voles, Clethrionomys glareolus, and much greater than those on greater white-toothed shrews, Crocidura
russula. Appreciable numbers of nymphal ticks, however, were
present solely on dormice. Dormice, therefore, serve as hosts to
nymphal ticks far more frequently than do other endemic small mammals.
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TABLE 1.
Density of the various small mammals in the Petite
Carmarque study site and of attached subadult I. ricinus
ticks on hosts
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To determine when rodents in our study site were most likely to acquire
spirochetal infection, we systematically sampled questing ticks from
ecotonal vegetation while simultaneously determining their feeding
densities on captured rodents. Nymphal vector ticks were collected from
vegetation most frequently during spring and early summer (Fig.
2). Their density declined during
midsummer and became nil by July. In contrast, such ticks continued to
parasitize dormice throughout the summer and into the fall. The
somewhat reduced tick burden that was observed on these animals during midsummer coincided with an increase in the density of the dormice following the birth of their offspring. Comparatively few nymphs attached to wood mice, and these were distributed throughout the transmission season. In an additional series of observations on 332 nymphs that were swept from vegetation, we found that 27% contained
spirochetes and infectivity was constant during April through June
(data not shown). We concluded that dormice experience intense exposure
to nymphal vector ticks beginning in April and continuing through
October.
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FIG. 2.
Seasonal distribution of nymphal I. ricinus
vector ticks questing on vegetation and attached to garden dormice,
E. quercinus, and wood mice, A. sylvaticus.
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We then compared the small-mammal fauna that was active along the
forested side of the Petite Carmarque ecotone with that which was
active along its grassy border. Garden dormice were far more frequently
trapped in the forest than were any other animals sampled, and they
were trapped in the forest about five times as frequently as they were
in the meadow (Table 2). Wood mice,
however, were dominant among the rodents captured in the meadow
but virtually absent in the woods. The yellow-necked mouse, A. flavicollis, occurred about three times as frequently in the meadow as in the forest, and bank voles were caught exclusively in the
meadow. Garden dormice are associated more closely with the forest than
are any other of the abundant small mammals in the study site.
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TABLE 2.
Distribution across the ecotone of the most abundant
small rodents endemic to the Petite Carmarque study site
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We compared the infectivity of these small mammals to the larval vector
ticks that infested them in nature. Although ticks acquired spirochetal
infection from virtually all dormice, infection was evident in less
than half of the other rodents and absent in the shrews that were
captured (Table 3). Each dormouse
contributed about five times as many infections to the vector
population as did mice, and voles contributed relatively few
infections. Spirochetal infection, therefore, is most prevalent in
dormice, and many more ticks acquire infection in the course of feeding
on these than on other small mammals in the study site.
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TABLE 3.
Prevalence of spirochetal infection in small mammals
captured in the Petite Carmarque study site and infectivity of these
hosts for larval I. ricinus ticks
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The spirochete infectivity of young garden dormice for vector ticks was
compared to that of mature animals. About half as many immature
(<50-g) dormice as mature (
50-g) dormice were captured, and
larval ticks infested all but a few (Table
4). Spirochetes were detected in
virtually all cohorts of ticks that were found naturally attached to
these rodents; infection was nearly universal in these hosts (82% of
small animals and 93% of larger animals; chi-square test, P = 0.23). Laboratory-reared larvae placed on these rodents,
however, acquired spirochetal infection more frequently when feeding on
larger than on smaller dormice (chi-square test, P = 0.004). Assuming that their tick loads were similar, each mature
dormouse would therefore contribute about half again as many infections
to the vector population as would an immature dormouse.
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TABLE 4.
Effect of age of garden dormice captured in the Petite
Carmarque study site on spirochete infectivity for
I. ricinus ticks
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We determined when replete larval vector ticks most frequently detach
from garden dormice. More than 98% of ticks infesting 47 such animals
detached within 2 days after detachment began and were included in our
analysis. About four-fifths of replete ticks detached during the
dormouse's diurnal period of sleep (Fig. 3). Ticks began to detach at about 2 h after the dormice became dormant. Because these animals sleep for
16 h each day, we estimate that all but a few replete ticks detach
while their dormouse hosts remain within their nests.
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FIG. 3.
Diurnal pattern of detachment of replete larval I. ricinus ticks from garden dormice, E. quercinus.
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Finally, we derived an overall estimate of the contribution of the
various abundant small rodents in the Petite Carmarque study site to
the frequency of spirochetal infection in the vector population. We
synthesized estimates of the trapping density of the various
candidate rodents, the feeding density of larval ticks on these hosts,
their prevalence of spirochetal infection, and the degree of
infectivity for vector ticks. The product of these estimates provided
the basis for this epizootiological comparison (Table
5). Garden dormice were far more
frequently infected and more infectious to vector ticks than were any
other rodent that was tested. The population of garden dormice
contributes five- to sevenfold more infections to the vector population
than the mouse population does.
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TABLE 5.
Relative contribution of various reservoir hosts to
spirochetal infection in the I. ricinus tick population in
the Petite Carmarque study site
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DISCUSSION |
The term "vectorial capacity" has been coined to express the
relative contribution of diverse vector mosquitoes to the force of
transmission of malaria pathogens (1). The concept derives directly from Macdonald's (2) landmark model analyzing
malaria transmission and ultimately from Ross' seminal work
(9). These authors identified and ranked various properties
of vector populations that together specify the number of new
infections deriving from each original infection per day. The
vector-related dynamics of tick-borne pathogens have been compared to
those that are insect-borne (8). The corresponding
properties of the reservoir hosts in which such cycles are completed,
however, have not similarly been analyzed. Our observations provide a
basis for identifying such components in the case of a tick-borne
zoonosis, Lyme disease.
The contribution of reservoir density to the force of transmission of a
pathogen may be complex. In the traditional malariological use of
vectorial capacity, the frequency of vector-reservoir contact would
vary inversely with reservoir density. A dense human population, for
example, would impede transmission, at least during the course of
feeding of those vectors then present in the site. In the case of the
agent of Lyme disease, the presence of numerous mice would facilitate
development of vector ticks by ensuring that they find hosts while
reducing the feeding density of the vector population relative to that
of the reservoir. This would delay the time that pathogens first are
introduced into individual reservoir hosts, thereby reducing the
cumulative proportion of infectious members of the reservoir
population. Spirochete transmission, therefore, would be most efficient
at some optimal density of reservoir hosts relative to that of vector ticks.
The tendency of larval I. ricinus vector ticks to feed on a
broader variety of mammals than do nymphal ticks increases the complexity inherent in these relationships. Although we find that the
density of larval ticks feeding on mice is similar to that on garden
dormice, far more nymphs feed on dormice than on mice. This implies
that dormice become infected by Ixodes-borne pathogens earlier in their lives than mice do, an effect that becomes exaggerated by the far greater life span of dormice. Infection would be
proportionately more prevalent in dormice; mice are relatively
"zooprophylactic" against Lyme disease spirochetes because the many
larval ticks that feed on these animals would fail to acquire
spirochetal infection.
The seasonality of the corresponding vector and reservoir hosts may
also affect transmission. Indeed, I. ricinus ticks are most
abundant in early summer, before the next generation of garden dormice
is born, and infectivity for ticks increases with age of this host.
This separation of generations is less pronounced in mice than in
dormice because mice are born earlier in the year (6),
before these ticks cease questing. Such a correspondence of vector
density with reservoir infectivity potentiates transmission.
The venue of spirochete transmission remains poorly defined. Human
hosts become infected most frequently during late spring and early
summer (12, 14), when nymphal vector ticks can most frequently be sampled from vegetation. Young dormice, however, appear
to be infected in our study site soon after they are born. We trapped
infected juveniles in mid-summer, when they begin foraging and when
only few ticks can be swept from vegetation. Numerous nymphal ticks
infest these animals, and this suggests that the juvenile dormice are
encountering ticks within their nests. Indeed, we found that replete
larval ticks detach from their hosts at a time of day when dormice
would be sleeping in their nests. Our finding of spirochetal infection
in virtually all garden dormice, regardless of age, confirms the
inference that the dormouse nest constitutes the main venue of
spirochete transmission.
The tendency of garden dormice to be parasitized by numerous nymphal
vector ticks combines with their long life span to render these animals
particularly effective as reservoir hosts for the agent of Lyme
disease. The multitude of nymphs that feed on them, in comparison to
those feeding on Apodemus mice, ensures that each of these
animals is infected early in life. These animals may encounter infected
nymphal ticks even before they are weaned, and once infected, such
animals remain infected for as long as 3 years, the mean life span of
garden dormice (10, 13). Indeed, their superior capacity as
reservoir hosts is increased by their spirochete competence; we find
that vector ticks become infected in the course of feeding on infected
garden dormice at least twice as frequently as they do while feeding on
other small rodents.
Each garden dormouse contributes about six times as many infections to
the vector population as does either kind of mice that we tested, in
part because they are more intensely exposed to nymphal vector ticks.
The resulting pattern of early and repeated infection may enhance
spirochete competence. Edible dormice, on the other hand, are only
about twice as effective as reservoir hosts as mice are (5).
Although both kinds of dormice infect virtually all ticks that feed on
them, garden dormice tend to be far more abundant than edible dormice
in their favored forested sites. In addition, the various rodents in
our relatively moist study site are parasitized by many more larval
ticks than are those in the relatively dry site in which edible dormice
have been studied. Their competence, nymphal feeding density, and
preference for a tick-permissive habitat combine to favor garden
dormice over other putative reservoir hosts of Lyme disease spirochetes.
| |
ACKNOWLEDGMENTS |
This study was supported by grant Ma 942/7-1 from the Deutsche Forschungsgemeinschaft.
We thank P. Knibiely and B. Scaar at the Reserve Naturelle de la Petite
Carmarque Alsacienne for granting permission to capture small mammals
and C. Vaterlaus for his valuable help in trapping and marking garden dormice.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Immunology and Infectious Diseases, Harvard School of Public Health, 665 Huntington Ave., Boston, MA 02115. Phone: (617) 432 1796. Fax:
(617) 738 4914. E-mail: drichter{at}hsph.harvard.edu.
| |
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Applied and Environmental Microbiology, February 1999, p. 707-711, Vol. 65, No. 2
0099-2240/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
