BioRisk 4( | ): 149-] 92 (20 | 0) cls to tiirs iccess journa 1]
doi: 10.3897/biorisk.4.58 RESEARCH ARTICLE B | O R IS

www.pensoftonline.net/biorisk

Mites and ticks (Acari)
Chapter 7.4

Maria Navajas', Alain Migeon', Agustin Estrada-Pefia’,
Anne-Catherine Mailleux?, Pablo Servigne*, Radmila Petanovié?

| Institut National de la Recherche Agronomique, UMR CBGP (INRA/IRD/Cirad/Montpellier SupAgro),

Campus International de Baillarguet, CS 30016, F-34988 Montferrier sur Lez, cedex, France 2 Faculty of
Veterinary Medicine, Department of Parasitology, Miguel Servet 177, 50013-Zaragoza, Spain 3 Université
catholique de Louvain, Unité d écologie et de biogéographie, local B165.10, Croix du Sud, 4-5 (Batiment Car-

noy), B-1348 Louvain-La-Neuve, Belgium 4 Service d’Ecologie Sociale, Université libre de Bruxelles, CP231,

Avenue E D. Roosevelt, 50, B-1050 Brussels, Belgium § Department of Entomology and Agricultural Zoology,

Faculty of Agriculture University of Belgrade, Nemanjina 6, Belgrade-Zemun, 11080 Serbia

Corresponding author: Maria Navajas (navajas@supagro.inra.fr)

Academic editor: David Roy | Received 4 February 2010 | Accepted 21 May 2010 | Published 6 July 2010

Citation: Navajas M et al. (2010) Mites and ticks (Acari). Chapter 7.4. In: Roques A et al. (Eds) Arthropod invasions in
Europe. BioRisk 4(1): 149-192. doi: 10.3897/biorisk.4.58

Abstract

The inventory of the alien Acari of Europe includes 96 species alien to Europe and 5 cryptogenic species.
Among the alien species, 87 are mites and 9 tick species. Besides ticks which are obligate ectoparasites,
14 mite species belong to the parasitic/predator regime. Among these species, some invaded Europe with
rodents (8 spp.) and others are parasitic to birds (2 spp). The remaining 77 mite species are all phytopha-
gous and among these 40% belong to the Eriophyidae (37 spp.) and 29% to the Tetranychidae (27 spp.)
families. These two families include the most significant agricultural pest. The rate of introductions has
exponentially increased within the 20" century, the amplification of plant trade and agricultural com-
modities movements being the major invasion pathways. Most of the alien mite species (52%) are from
North America, Asia (25%), and Central and South America (10%). Half of the ticks (4 spp.) alien zo
Europe originated from Africa. Most of the mite species are inconspicuous and data regarding invasive
species and distribution range is only partially available. More research is needed for a better understand-

ing of the ecological and economic effects of introduced Acari.

Keywords

Europe, alien, mite, tick, Acari, Eriophyidae, Tetranychidae, biological control, Tetranychus evansi, Oligo-
nychus perseae, Polyphagotarsonemus latus, Brevipalpus californicus, Aceria sheldoni, Aculops pelekassi, Der-
matophagoides evansi, Varroa destructor

Copyright M. Navajas et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which
permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

150 Maria Navajas et al./ BioRisk 4(1): 149-192 (2010)

7.4.1. Introduction

The subclass Acari, which includes mites and ticks, forms an important part of the
class Arachnida, with a worldwide distribution and with over 55,000 (Krantz and
Walter 2009) species described to date. An estimate of up to halfa million to a million
more species await discovery (Krantz and Walter 2009). Mites and ticks are a very di-
verse group ranging in size from about 0.08 mm up to | centimetre long. Acari differ
from others Arachnida by the fusion of the abdominal segments as in Araneae (spi-
ders) and from spiders by the presence of a gnathosoma containing mouthparts, the
fusion of the posterior part of the prosoma (the podosoma, bearing legs) and fusion
of an opisthosoma into an idiosoma (Evans et al. 1996). Most species are free living
and have different trophic modes, including phytophagous, predators feeding on a
variety of small invertebrates, fungivores and detritivores. Some species have devel-
oped complex parasitic relationships with both vertebrate and invertebrate animals.
A number of acarine groups are injurious to crops and to livestock, both because of
their feeding activities and because of their capacity as vectors for a variety of disease
organisms to their plant or animal host. While the Oribatida is an important group
(more than 6,000 species) having a key role in soil equilibrium, data regarding inva-
sive species and distribution range remain largely unavailable. Ticks are very peculiar
acarines, since they are obligate ectoparasites. In this sense they form a very homog-
enous group, with the order Ixodida composed of only three families. In this chapter,
the two groups of Acari, mites and ticks, will be treated separately. The ticks will be
presented through the description of a few significant case studies. By contrast, mites
being much diversified in their biology and habitat use, and being truly ubiquitous,
will be presented systematically.

Mites have successfully colonized nearly every known terrestrial, marine, and
freshwater habitat. The most studied and observed invaders are found among the phy-
tophagous mites of the families Tetranychidae and Eriophyidae, which include impor-
tant agricultural pests. There is a growing awareness of the economic relevance of erio-
phyids as crop pests, including their importance as vectors of plant viruses, their role as
alternative food for predators of plant pests, and their potential as weed control agents
(Sabelis and Bruin 1996). A description on spider mite biology and their control is
presented in the extensive review by Helle and Sabelis (1985). In addition to plant-
feeding mites, a second group includes the alien parasitic mites. Among them, some
invaded Europe with rodents such as muskrats (six alien species of mites), and brown
rats (two aliens), while others are bird parasites (two species). Dermatophagoides evansi
(Pyroglyphidae) is not associated with rodents and it has probably been accidentally
introduced by humans (Bigliocchi and Maroli 1995,Hughes 1976, Thind and Clarke
2001). A single species in the family Varroidae, Varroa destructor, is alien to Europe (De
Rycke et al. 2002, Griffiths and Bowman 1981).

Ticks are important parasites of livestock, wild animals, and humans. After their
parasitic phase, they spend most of their life cycle outside their hosts, where prevail-
ing climate conditions may constrain their ability to colonize a given territory. While

Mites and ticks (Acari). Chapter 7.4: 151

some tick species are highly restricted to particular combinations of climatic variables,
or have defined host species, others may occur in widely variable climate conditions
and have catholic feeding habits. Some species of ticks can be considered as invasive
species, since the uncontrolled movements of domestic animals may introduce alien
species into Europe or disperse some species outside their native distribution ranges.
The introduction via large-bodied host vectors (such as passerine birds) and the un-
controlled importation of reptiles, are important means for colonizing newly available
areas. Furthermore, one species of tick, Rhipicephalus sanguineus, is spreading in parts
of Europe out of its current range because of the movements of domestic dogs.

7.4.2 Taxonomy of the mite species alien to Europe

A total of 101 mite species have been considered as alien to Europe, including 96 spe-
cies shown to have originated from other continents and 5 cryptogenic species (Table
7.4.1). These species involve 16 different families of mites (Figure 7.4.1). In addition,
Table 7.4.2 provides some examples of mite species alien im Europe; i.e., European spe-
cies introduced from one part of Europe to another where they are not native.

Alien mites belong to two super orders, Acariformes (Actinotrichida) and Para-
sitiformes (Anactinotrichida). Most of these species belong to two orders of Acari-
formes, Prostigmata and Astigmata. Prostigmata includes the three most important
superfamilies:

* Tetranychoidea comprises two main families containing alien mites. The
Tetranychidae family, or spider mites, includes 1,250 described species (http://www.
montpellier.inra.fr/CBGP/spmweb/). Among them, 100 can be considered as pests
and 10 as major pests of agricultural crops. All stages are phytophagous and feed on pa-
renchyma cells. No viruses associated with spider mites have been observed. The most
widely distributed species is the highly polyphagous and ubiquitous Tetranychus urticae
(two spotted spider mite), found on nearly 1,000 plant species. In Europe, alien spider
mites are generally more specialized and occur on a single genus or family of plants.
Due to their minute size (200 to 900 um) typical of many species of Acari, spider mites
remain undetected until major plant damage occurs. The members of another family,
Tenuipalpidae, or false spider mites, are important obligate phytophagous mites. They
are elongate, dorsoventrally flattened and usually have a reddish colour.

* Eriophyoidea includes three families:

— Eriophyidae, to which belong ca. 88% of all known Eriophyoidea in the
fauna of Europe (Fauna Europaea 2009). These are vermiform, four legged mites. The
family includes important economic pests of broadleaved plants. All known mite vec-
tors of plant pathogens and nearly all gall-forming species belong to this family. About
half are vagrants. Most of the species in the genera Aceria and Eriophyes cause spe-
cific galls on the leaves, green twig, flower buds, vegetative buds, or fruit of the hosts
(Oldfield 1996). Others, especially Epitrimerus, Phyllocoptes, Aculops and Aculus cause

discolouration and other non-distortive damage to their hosts.

152 Maria Navajas et al./ BioRisk 4(1): 149-192 (2010)

No. species No. species
1200 800 400 0 0 10 20 30 40 50
l 1 | 1 | rl
892 Eriophyiidae
Tetranychidae
Ixodidae
Tenuipalpidae
Phytoptidae

Listrophoridae
Phytoseiidae
Laelapidae
Diptilomiopidae
Macronyssidae
Tarsonemidae
Epidermoptidae
Myocoptidae
Pyroglyphidae
Varroidae

Native species

Figure 7.4.1. Relative importance of the mite families in the alien and native fauna in Europe. Families
are presented in a decreasing order based on the number of alien species. Species alien to Europe include
cryptogenic species. Only the most important families of native species (> 50 spp.) have been considered.

The number over each bar indicates the number of species observed per family.

— Phytoptidae, which are obligate phytophagous and gall mites, with a high
degree of specificity. They are also vermiform and four-legged. The family Phytoptidae
is well represented on conifers (half of the described phytoptid species) and monocots.
Phytoptidae is less represented than Eriophyidae or Diptilomiopidae on dicotyledons.
Four alien species out of a total of 56 species have been reported in the fauna of Europe.

— Diptilomiopidae, which are predominantly leaf vagrants, only inhabiting
leaves of dicotyledons, and rarely causing notable damage to their hosts (Keifer 1975).
Two monotypic genera are known from only two families of monocotyledons (Poaceae
and Palmae) occurring in the tropics. Rhyncaphytoptus species are mainly represented
on several families of deciduous trees in the Holarctic region. Two alien species have
been reported, out of the total 61 in the European fauna.

* ‘'Tarsonemoidea represented by the family Tarsonemidae includes economically
important mites. Most of them are mycophagous. Some species are phytophagous,
whereas others are parasites of bark beetle eggs, or predators of tetranychid eggs. The
most redoubtable pest species in the family is the broad mite, Polyphagotarsonemus latus
(=Hemitarsonemus latus), which was described in 1890 and has recently been redefined
and considered as being a species complex (Gerson 1992).

The order Astigmata is less represented in the alien fauna. A few species be-
long to the super-family Sarcoptoidea, and especially to families Listrophoridae
and Myocopidae. Members of Listrophoridae are usually small, elongate mites and
are skin or hair parasites of mammals. The palpae and/or legs I-II are often highly
modified for grasping hairs. Four species of Listrophoridae mites have invaded Eu-
rope, grasped to the fur of muskrats: Listrophorus americanus, L. dozieri, L. faini
and L. validus (Sefrova and La&ttivka 2005). Myocopids, or hair mites, live on skin
of marsupial and rodents (Bauer and Whitaker 1981, Sefrova and Lasttivka 2005,

Mites and ticks (Acari). Chapter 7.4: 153

Whitaker 2007). Myocoptes ondatrae is an ectoparasite that has invaded Europe
by grasping the fur of muskrats (Bauer and Whitaker 1981, Sefrova and La&tivka
2005, Whitaker 2007). Other species belong to the super-family Acaroidea and
families Epidermoptidae and Pyroglyphidae. Epidermoptidae are skin parasites of
birds. Epidermoptes bilobatus causes avian scabies. Pyroglyphidae are external para-
sites living on bird feathers or are nidicolous. Dermatophagoides evansi feeds on hu-
man detritus, and lives in house dust as well as within bird nests (Piotrowski 1990,
Razowski 1997).

Among the super-order Parasitiformes (Anactinotrichida), aliens belong to or-
ders Ixodida and Mesostigmata. Ixodida is represented by the species in the family
Ixodidae, which is treated in a separate section at the end of the chapter. Alien Mes-
ostigmata belong to superfamilies Ascoidea and Dermanyssoidea. The first super-
family is represented by a single family with aliens, Phytoseiidae, which are predators of
spider mites. In Europe, species such as Phytoseiulus persimilis, Amblyseius (Neoseiulus)
californicus and Iphesius (Amblyseius) degenerans are used as biological control agents
against phytophagous pests (Bartlett 1992, Croft et al. 1998, Easterbrook 1996, EPPO
2002, Garcia Mari and Gonzalez-Zamora 1999, Helle and Sabelis 1985, McMurtry
and Croft 1997). Three families of Dermanyssoidea contain alien species. Varroidae
mites are ectoparasites of honeybees. Varroa destructor is at present the most important
parasite of Apis mellifera (L.). Varroa feeds on the haemolymph of adult, larval and
pupal bees. Laelapidae mites live in soil, are nidicoles or parasitize small mammals
and insects. Ondatralaelaps multispinosus is an ectoparasite of muskrats (Sefrova and
Lasttivka 2005). Laelaps echidninus is a common worldwide ectoparasite of spiny rats,
wild brown rats and is occasionally found on the house mouse and cotton rat (Whar-
ton and Hansell 1957). Macronyssidae mites are haematophagous, have a large dorsal
shield, prominent chelicerae and inconspicuous body setae (Easterbrook et al. 2008).
Ornithonyssus bacoti is a parasite of rats, living in rat nests and their surroundings (Cole
et al. 2005, Easterbrook et al. 2008, Fan and Petit 1998, Whitaker 2007). Ornithonys-
sus bursa is a natural parasite of common birds including pigeons, starlings, sparrows,
Indian mynahs, poultry, and some wild birds, such as the robin (Berggren 2005).

7.4.3 Temporal trends of introduction in Europe of alien mite species

The rate of arrival of alien mites in Europe is increasing exponentially (Figure 7.4.2).
An average of 2.1 alien species was newly recorded per year in Europe during 2000-
2007 whereas only half this number was recorded during the period 1950-1974 (1
species/year). However, large differences were found between families.

The first records for Europe of all alien Tetranychidae are extensively documented
in this chapter. There are no records reported before 1950; however, only few taxono-
mists were specialized on the family before this date. Since the second half of the 20"
century, tetranychid species have been reported at an average rate of one new species
every two years, with an acceleration of reports (one species per year) since 2000.

154 Maria Navajas et al. / BioRisk 4(1): 149-192 (2010)

Mean number of new alien species
recorded per year during the period
0 | 2 3

1492-1799
1800- 1849
1850-1899
1900-1924
1925-1949
1950-1974
1975-1999
2000-2007

Time period

Figure 7.4.2. Temporal changes in the mean number of records per year of mite species alien to Europe
from 1800 to 2009. The number over each bar indicates the absolute number of species newly recorded

per time period.

Most of these mites represent agricultural pests, and therefore have been widely studied
which explains the overrepresentation of crop pest species as Tetranychidae aliens.

The mean number of records of Eriophyoidae species alien to Europe increased
rapidly during the third quarter of the 20" century. Only one species Aceria alpestris,
which is alien in Europe, was recorded within the period 1850-1899. This species
was described from the host plant Rhododendron ferrugineum L. from Tirol (Austria).
The species was later recorded in mainland Italy, Czech Republic, Slovenia and Ser-
bia, but it is not clear if it was associated with cultivated Rhododendron. Species re-
corded intensively between 1900-1924 (although described from Germany in 1857)
are categorized as cryptogenic (Eriophyes pyri, the pear blister mite) or alien in Eu-
rope, like Aculus hippocastani (recorded in 1907, but probably introduced in Europe
from the 17" century when its host plant Aesculus hippocastanum L. was intensively
cultivated), and Aceria loewi (probably introduced in the 16™ century when lilac
started to be cultivated in France). Aculops allotrichus, which is alien to Europe, was
recorded in 1912 but was probably, introduced with its host Robinia pseudoacacia L.
which was for the first time introduced into France at the beginning of 17° century.
Aceria erinea and A. tristriata were suspected to have an Asian origin and have been
designated as aliens. They were recorded on 1903, but probably were present on its
host, Persian walnut, in the Balkans and South Europe much earlier. Only one species
in the Eriophyoidae was recorded between 1925-1949, e.g. Aceria petanovicae, the
lilac rust mite. Being for long time known under the name of Aculops massalongoi the
species is alien in Europe.

Mites and ticks (Acari). Chapter 7.4: 155

Six alien species to Europe were recorded between 1950-1974. Two pests of citrus,
Aceria sheldoni (citrus bud mite) and Aculops pelekassi (citrus rust mite) and the azalea
mite Phyllocoptes azaleae, are suspected to have been introduced from Asia. Character-
istic symptoms of deformed lemon fruits caused by A. sheldoni were drawn by Battista
Ferrari in Italy in 1664 (Ragusa 2002). Three pests have been reported from North
American maple trees (Acer negundo L., A. saccharinum L. and A. rubrum L.), i.e.
Shevtchenkella brevisetosa, Vasates quadripedes and Rhyncaphytoptus negundivagrans. The
25 species recorded during the period 1975-1999 almost all have a North American
origin (only Epitrimerus cupressi is designated as cryptogenic, because of the Mediter-
ranean origin of its host Cupressus sempervirens L.). During the period from 2000 to
2007, one species alien to Europe, Rhyncaphytoptus bagdasariani, has been recorded as
being introduced from Asia and the serious pest Aceria fuchsiae (a species on the Euro-
pean quarantine list) was introduced from South America. As for other phytophagous
mites, the most probable explanation for the acceleration in the pace of introductions
of alien eriophyids is intensification of international trade. Most of these alien species
inhabit ornamental trees and shrubs, flowers and potted ornamental plants.

Some alien parasitic mites have invaded Europe with rodents such as muskrats and
brown rats. The muskrat (Ondatra zibethicus L.) is an invasive rodent native to North
America. It was introduced around 1905, by humans as a fur resource in several parts
of Europe, as well as in Asia and South America. Six species of mites, native from
North America (Bauer and Whitaker 1981, Whitaker 2007), have invaded Europe
grasping its fur (Glavendekié et al. 2005, Sefrova and Lasttvka 2005). The first report
of muskrat mites was recorded in 1955, and a second in 2000, both in Czech Republic.
Two other parasitic species, Laelaps echidninus and Ornithonyssus bacoti, are also alien
ectoparasites of rodents that have invaded Europe and were identified in the 1950's
(Sefrové and Lagtitvka 2005), but the exact pathway of introduction is not known.
One possible vector is the wild brown rat, Rattus norvegicus (Berkenhout). Thought to
have originated in northern China, this rodent spread in Europe in the middle ages
and is now the dominant rat in the continent.

Birds are vectors of a second group of alien parasitic mites, that include Epider-
moptes bilobatus and Ornithonyssus bursa, both identified in the 1950's, in the Czech
Republic (Sefrov4 and Lagtivka 2005). The exact route of introduction is not known
with confidence, but a possible vector is the chicken (Gallus gallus domesticus L.). In
the 20“century, with the intensifications of poultry production, concerns have been
raised about the increasing risk of transfer of diseases and mites (from chickens to na-
tive bird species).

Whereas the exact date of arrival of alien mites is generally unknown, deliberately
released biological control agents are the exception to this rule. Among them, three
phytoseiids are mainly used as predatory species against pests (McMurtry and Croft
1997). Phytoseiulus persimilis was introduced for the first time in the 1970's in Bulgaria
and Czech Republic (EPPO 2002, Sefrov4 and La&ttivka 2005). Neoseiulus californicus
was introduced for the first time in 1991 in Great Britain (EPPO 2002). It was also in-
troduced at the same period in the Czech Republic (EPPO 2002, Sefrovd and Lagtitvka

156 Maria Navajas et al./ BioRisk 4(1): 149-192 (2010)

2005). The third introduced mite is /phiseius degenerans. It is native from the Mediter-
ranean region and was introduced for the first time in 1993 in Czech Republic (EPPO
2002, Sefrov4 and La&tivka 2005). Nowadays, these three biological agents have been
introduced in most European countries.

7.4.4 Biogeographic patterns of the mite species alien to Europe

7.4.4.1 Origin of the mite species alien to Europe

Figure 7.4.3. presents the region of origin of the 101 alien species of mites. Most of the
alien mite species (52%) came from North America, then from Asia (25%), and Cen-
tral and South America (10%). The origin of phytophagous alien mites can usually be
inferred from the origin of the host plant. These mites are dispersed over long distances
mainly by the introduction of plant material and spread further by plant cultivation in
newly colonized regions. Aerial distribution is possible and most frequent, but mainly
over short distances (Margolies 1993, Margolies 1995). In the case of highly polypha-
gous species such as several Tetranychidae, their ubiquity and highly diverse host uses
might be misleading and the origin can be difficult to ascertain. Twelve out of 27 alien
Tetranychidae originated in North America, nine in Asia and only five in Central and
South America. Temperate regions provide the majority of the alien species (16 vs. 11
for tropical areas).

The majority of eriophyoid species are mono- or oligophagous and are distributed
within the host range. North America appears to be the dominant source of the alien
eriophyoid fauna with half of the species originating from this continent. Around 26%
of species originate from Asia, and less than 10% from South America. A few species
are designated as cryptogenic or with questionable origin. For example, Rhyncaphy-
toptus negundivagrans, although described from Hungary, probably originated from
North America with its host plant, Acer negundo. Whereas the camellia rust mite, Co-
setacus cameliae (described from California) was probably introduced to Europe from
the USA, it probably has an Asian origin considering that Camelia japonica L. comes
from subtropical and tropical regions of Southeast Asia. The pouch gall mite of plum
leaves, Eriophyes emarginatae, first discovered in the USA, has also been recorded in
Serbia and Japan. This mite is very closely related to the European E. padi (Nalepa)
(Petanovi¢ 1997) and may even be the same species, with synonymous names (Keifer
1975). Epitrimerus cupressi was described from North America, but according to the
origin of its host plant Cupressus sempervirens, which is from the Mediterranean re-
gion, the mite probably has an European origin too. The gall mite Phytoptus hedericola
(Phytoptidae) is native from South Africa (Glavendekié et al. 2005), and Trisetacus
chamaecypari (Phytoptidae) from North America (Ostoja-starzewski and Halstead
2006, Smith et al. 2007).

Among the false spider mites (Tenuipalpidae), Brevipalpus californicus, B. obovatus
and Tenuipalpus pacificus originated from Central and South America, and Florida

Mites and ticks (Acari). Chapter 7.4: Le?

North America

51.5%
_C& S America
9.9%
___ Tropical
a. 3.0%
Cryptogenic
6.9%
| Africa
| 4.0%
|
Asia
24.8%

Figure 7.4.3. Origin of the mite species alien to Europe.

(USA) (Denmark 1968, Manson 1967). Six alien species of rodents bear parasitic mites
originating from North America, and belong to the families Listophoridae (four spe-
cies), Laelapidae (one species), and Myocoptidae (one species). In their native country,
they are all ectoparasites of murskrats. There are also some bird parasites: one species of
Epidermoptidae, Epidermoptes bilobatus, is an ectoparasite native from South Asia, and
Ornithonyssus bursa is probably native from Trinidad.

A single Varroa species, V. destructor, is alien to Europe (Grifhths and Bowman
1981). Its native range is South East Asia, where it was originally confined on its
original host, the Asian honeybee, Apis cerana F. This mite came to be a parasite of the
European honeybee, Apis mellifera, in the mid-twentieth century. Importation of com-
mercial A. mellifera colonies into areas with A. cerana brought the previously allopatric
bee species into contact and allowed V. destructor to switch to the new host

7.4.4.2 Distribution in Europe of the alien mite species

Alien mite species are not evenly distributed throughout Europe. Large differences in
the number of aliens are noticed between countries (Figure 7.4.4) but it may reflect
differences in sampling efforts and in the number of local taxonomic specialists.

Among the Tetranychidae, 19 alien species are found around the Mediterranean
Basin and 12 in the rest of Europe. With relatively warm winters, the Mediterranean
region provides suitable climatic living conditions for many species of temperate cli-
mates, but also for the establishment of many species of tropical or sub-tropical origin.
Except for Panonychus citri and the cryptic species Tetranychus ludeni, which can be
found in glasshouses in Europe, all tropical alien spider mites are restricted to the area
around the Mediterranean Sea.

158 Maria Navajas et al./ BioRisk 4(1): 149-192 (2010)

Number of alien species

nodata [| 6-10 SN 21-31
| »

Figure 7.4.4. Comparative colonization of continental European countries and islands by mite species

alien to Europe. Archipelago: | Azores 2 Madeira 3 Canary Islands.

Most alien Eriophyids have a very restricted distribution. More than 40% of the spe-
cies have been observed in only one country (17 species), more than 40% (21 species) in
2—5 countries, and approximately 20% (7 species) in 6-11 countries. Eight European
countries have no recorded occurrence of alien eriophyoids to date. Only one species,
the pear blister mite Eviophyes pyri (which has cryptogenic status), has been recorded
from 32 European countries. Besides FE. pyri, the more widely distributed eriophyoid
species are: Aceria erinea, A. loewi, A. sheldoni, Aculops pelekassi and Eriophyes canestrini.
The gall mite Phytoptus hedericola (Phytoptidae) entered Europe in 2002 and has been
observed in Serbia (Glavendekié et al. 2005). Trisetacus chamaecypari (Phytoptidae) en-
tered Europe in 2002 (Ostoja-starzewski and Halstead 2006, Smith et al. 2007). The
status of Typhloctonus squamiger (Phytoseiidae), a poorly known phytophagous mite
found on trees in Italy since 1991 (Rigamonti and Lozzia 1999), is questionable.

The distribution of biological agents belonging to the Phytoseiidae family is well-
known. Phytoseiulus persimilis is now present in nearly all of Europe (Table 7.4.1)

Mites and ticks (Acari). Chapter 7.4: 159

(EPPO 2002). Neoseiulus californicus has been found in the same countries except Aus-
tria, Hungary, Morocco, Slovakia, Sweden and Turkey. The third introduced phytoseid
mite, [phesius degenerans, is also present in several countries (Table 7.4.1).

The broad mite Polyphagotarsonemus latus (Tarsonemidae) is now cosmopolitan. In
Europe, it was reported for the first time in 1961 and since then the mite has invaded
almost all countries (Table 7.4.1) (CAB-International 1986, Fan and Petit 1998, Na-
tarajan 1988, Parker and Gerson 1994); it is potentially now in all parts of Europe.

Three species of false spider mites (Tenuipalpidae) are major invaders in Europe.
Brevipalpus californicus, found in 316 orchid and tree species of 67 genera and 33
families, was first recorded in 1960 and is mainly observed in citrus trees around the
Mediterranean basin (Denmark 1968, Manson 1967). The privet mite, Brevipalpus
obovatus is found in 451 herb, ornamental and shrub species (19 genera, 55 families)
(Manson 1967) has been recorded from Austria, Cyprus, France, Germany, Israel,
Netherlands, Serbia and Spain (Manson 1967). Tenuipalpus pacificus (the Phalaenopsis
mite) is found in greenhouses of Phalaenopsis orchids in Germany, Great Britain, Neth-
erlands and Serbia (Denmark 1968, Manson 1967).

The introduced range of Varroa destructor is practically worldwide. It was first re-
ported in Eastern Europe in the mid- 1960s and it has spread rapidly all over the con-
tinent. Two different genotypes, characterized by mitochondrial DNA sequences, have
spread as independent clonal populations (Solignac et al. 2005), the Korean and the
Japanese haplotypes, the latter having been found, besides Asia, in the Americas only.

7.4.5. Pathways of introduction in Europe of alien mite species

Although colonisation routes are poorly documented for the Tetranychidae, it is known
that many species travel with their host plant. Small organisms like tetranychids are
easily transported with plant material (leaves and in bark crevices). Only five species
feed mainly on herbaceous plants (Tetranychus evansi, T: macfarleni, T. sinhai, Schizo-
tetranychus parasemus, and Petrobia lupini), whereas all other alien species in the family
feed on perennial shrubs.

As for tetranychids, the horticultural and ornamental trade is probably the most
important factor for accidental introductions of almost all species of alien Eriophyoi-
dae. Just a few species of Eriophyoids are on European quarantine lists, as plants are
rarely inspected for presence of these mites. Infested plant material is not regularly
intercepted at borders even in the case of important pests such as the grape rust mite
Calepitrimerus vitis (Nalepa) or the blackberry fruit mite Acalitus essigi (Hassan), which
are frequently disseminated with plant seedlings. During recent decades more than
50% of aliens were imported with ornamental plants. Among eriophyids, which are
obligate plant parasites, only one trophic group which is associated with weeds, can be
subject to intentional introduction. Although these mites were recently nominated as
potential agents for classical biological control of weeds (few species are imported for
this purpose), they have not yet been used for this purpose in Europe. Four species of

160 Maria Navajas et al. / BioRisk 4(1): 149-192 (2010)

alien eriophyoids which were probably introduced along with their host plants may
have the potential as biological control agents of serious alien weed pests. In particular,
Aceria ambrosiae can be used against the allergenous weed Ambrosia artemisifolia L.
that was imported into Europe from North America.

As for other phytophagous species, the broad mite Polyphagotarsonemus latus (Tar-
sonemidae) has mainly been dispersed by human activities, but also by wind or in-
sect transfer. Movement by insects should not be neglected: this concerns almost only
females that get attached to the legs of aphids and the whiteflies Bemisia argentifo-
lii (Bellows and Perring), Bemisia tabaci (Gennadius) and Trialeurodes vaporariorum
(Westwood) (Homoptera: Aleyrodidae) (Fan and Petit 1998, Natarajan 1988, Parker
and Gerson 1994).

Although including important crop pest species, the dispersal potential of false
spider mites (Brevipalpus spp.), Tenuipalpidae, remains unclear (Childers et al.
2003a, 2003b).

Intentional introductions of mites represent a low proportion of alien arrivals.
Only three phytoseeid predators were introduced purposely for biological control
and have established. Some of these biological control agents were released in the
field but others were first released in glasshouses, and then escaped and became es-
tablished outdoors.

International travel and commerce has facilitated the dispersal of Varroa destruc-
tor. Once established in a new region, the mite spreads using drifting, robbing, and
swarming behaviour of the host. Human mediated varroa dispersion also occurs via
apicultural practices.

7.4.6. Ecosystems and habitats invaded in Europe by alien mite species

Alien mites established in Europe predominantly live in agrosystems or anthropogenic
environments (ca. 92%; Figure 7.4.5). This is especially verified in Tetranychidae and
Eriophyidae. Among eriophyoids, some are present in man-made habitats, parks and
gardens (22 species), agricultural lands (13 species), and greenhouses (10 species); very
few species inhabit woodland and forest, costal, alpine or sub alpine habitats. Most
alien species in this superfamily are leaf vagrants (13 species). Twelve species cause
leaf galls, erinea* and leaf rolling, 11 cause leaf and/or fruit russeting or other type of
discolouration, six live predominantly in buds causing bud galls, three species cause
stunting of whole plants and/or plant organs and two cause flower and/or fruit defor-
mations. Among the leaf gall makers, the most important horticultural pests are dis-
tributed in many European countries, such as E. pyri, A. erinea, A. tristriata or, such as
A, fuchsiae which is on quarantine lists. Among the rust mites, only a few are important
horticultural pests like A. theae, A. pelekassi and C. carinatus. Most species are pests of
ornamental trees, shrubs or flowering plants, having an important aesthetic impact
on plants in parks and streets in most European towns and cities (i.e. A. gleditsiae,
A. ligustri, A. petanovicae, S. strobicus, P chrysanthemi), an exception being A. sawatch-

Mites and ticks (Acari). Chapter 7.4: 161

Percentage of alien mites
living in the habitat

0 10 20 30 40 50

Coastal areas-B 0
Riparian habitats- C Ml 6
Mires and bogs- D~ 0
Grasslands- E {J 2
Heathlands- F (il
Woodlands and Forests- G (i
Inland without vegetation- H~ 0
Agricultural lands- | EE 33
Parks and gardens- |2 [i 42
Buildings, houses- | NN 11
Greenhouses- ]|00 MM 13

Unknown {il 5

Habitats

Figure 7.4.5. Main European habitats colonized by the established alien species of mites. The number
over each bar indicates the absolute number of alien dipterans recorded per habitat. Note that a species

may have colonized several habitats.

ensae which inhabits weeds. Two Eriophyoids which cause plant stunting, A. paradi-
anthi and T: califraxini, are important pests of ornamental plants and one species, A.
ambrosiae, is a potential biocontrol agent against the alien weed Ambrosia artemisifolia.
Two species which cause flower and/or fruit deformations, A. alpestris and A. sheldoni,
are respectively pests of Rhododendron and citrus trees.

The gall mite Phytoptus hedericola lives on ivy (Hedera helix L.) and Trisetacus laricis
switched from American larch to European larch (Larix decidua Mill.).

The broad mite Polyphagotarsonemus latus (Yarsonemidae) has a very short life
cycle of a few days, damaging crops abruptly. Being highly polyphagous, the species
has been reported on 57 plant families (Gerson 1992) both in open field crops and
in greenhouses. This is an important pest of crops and ornamental plants such as
azaleas, castor bean, chillies, citrus fruits, cotton, cucumber, mango, papaya, pep-
per, potato, sweet potato, tea, tomato and winged bean (Gerson 1992, Glavendeki¢c
et al. 2005, Heungens 1986, Raemaekers 2001). Nevertheless, in Europe this mite
is found mainly in greenhouses because the mite cannot survive winter conditions
outdoors.

False spider mites (Brevipalpus spp.; Tenuipalpidae) present a risk of invasion in
greenhouses. Brevipalpus obovatus (the privet mite) is found on ornamentals and shrubs
like citrus and azaleas and could become of great importance in glasshouses for orna-
mentals (Childers et al. 2003a, 2003b). Tenuipalpus pacificus (the Phalaenopsis mite)
is one of the rare monophagous mites in the family, but it is a very destructive pest of
orchids under greenhouses, mainly because it has several generations per year and has
a two-month life cycle (Denmark 1968, Manson 1967).

162 Maria Navajas et al./ BioRisk 4(1): 149-192 (2010)

A Pyroglyphidae mite, Dermatophagoides evansi, is a cosmopolitan free-living spe-
cies, often encountered in synanthropic situations and has probably been accidentally

introduced by humans (Bigliocchi and Maroli 1995, Hughes 1976).

7.4.7. Ecological and economic impact of alien mite species

Seven species of alien Tetranychidae are important pests. On citrus, four alien species
are found: Panonychus citri, Eotetranychus lewisi (also on grapes) Eutetranychus banksi
and £. orientalis, the last presently spreading to Southern Portugal and Spain from
Huelva to Murcia and Alicante. Oligonychus perseae is found on avocado and produces
very severe damage in southern Spain (Malaga, Granada and Huelva) and in the Canary
Islands. Stigmaeopsis celarius is found on bamboos and causes important visual damage
to these ornamental plants. Tetranychus evansi is found on solanaceous crops and can
reach very high density as observed in France, Spain and Canary Islands. All these mites
are present in the Mediterranean Basin, which appears to be the region most threatened
by alien species. Only two of these species can be found outside the Mediterranean
area: Panonychus citri, especially in glass-houses, and Stigmaeopsis celarius.

In humid citrus-growing regions of the world, eriophyoid mites are considered to be
the major mite pests (Jeppson et al. 1975, McCoy 1996). Two alien species, Aceria shel-
doni and Aculops pelekassi, distributed worldwide, are among the most important pests in-
festing citrus. The pear blister mite, Eriophyes pyri, widely distributed in Europe, probably
does little harm to the tree, but in severe infestations, the tree leaves may become disfig-
ured, and most importantly the mite may damage fruits (Easterbrook et al. 2008). Besides
fruit orchards, species in the superfamily inhabiting wild trees in natural forests are: Aceria
tristriata and A. erinea which appear to be the most common and most injurious erio-
phyoids found on Juglans regia L. (Castagnoli and Oldfield 1996). Among the five species
of eriophyoid mites reported from commercially important beverage crops in different
parts of the world, wherever tea is grown, the purple tea mite Calacarus carinatus and the
pink tea mite Acaphylla theae are economically important in Southeast Asian countries,
and in India (Channabasavanna 1996). Both species are aliens to Europe, reported from
mainland Italy (A. theae) and from Hungary, Poland and Spain (C. carinatus). Records
concerning host plant range in the case of C. carinatus are, besides tea, Viburnum opulus
L. and Capsicum annuum L. (Amrine and Stasny 1994). Bearing in mind that congeneric
Calacarus citrifolii has an extremely wide host range (Oldfield 1996), this might be also
the case for C. carinatus, which would convey on the latter serious pest status in Europe.
Economic impact of alien pest species of eriophyoids on ornamentals has been observed
for Aculops gleditsiae on honey locust, Aceria petanovicie on lilac, Aculops ligustri on privet
hedges, Aculops allotrichus on black locust, Reckella celtis on Celtis australis L., Shevtchen-
kella brevisetosa on Acer negundo, Vasates quadripes on silver maple, Phytoptus hederae on
English ivy, and Setoptus strobicus on Pinus strobus L. (Petanovi¢é 2004). Flower and foliage
aesthetic impact has been observed indoors (business centers, restaurants, shopping cent-
ers, hotels, etc.) for a few alien eriophyoids, Cecidophyopsis hendersoni causing a powdery

Mites and ticks (Acari). Chapter 7.4: 163

10kV X900 20m 0000 1006 SEI

me

Figure 7.4.6. Alien mites and their damage. a Curling and rusting of black locust leaves caused by Acu-
lops allotrichus b Chlorotic and misshapen leaves of Acer negundo caused by Shevtchenkella brevisetosa (left)
and uninfested leaves (right) ¢ Leaf rusting of lilac leaves caused by Aceria petanovicae d Aceria petanovi-
cae, dorsal view-SEM photograph e Rusting of Pinus strobus needles caused by Setoptus strobacus f Setoptus
strobacus eggs, juveniles and adults between needles of Pinus strobus g Leaf distortion and unopened da-
maged flower buds of chrysanthemum caused by Paraphytoptus chrysanthemi h Deformed flower heads of
chrysanthemum caused by Paraphytoptus chrysanthemi i Colony of Cecidophyopsis hendersoni on Yucca leaf
j Panonychus citri. (a-i Credit: Radmila Petanovic; j Credit: Alain Migeon).

appearance on Yucca leaves, Cosetacus cameliae causing bud rust and abortion on flower
buds of Camelia plants, and Paraphytoptus chrysanthemi causing deformed buds, hairy
leaves and rust on Chrysanthemum (Petanovic 2004).

The broad mite Polyphagotarsonemus latus (Tarsonemidae) and the false spider
mites (Brevipalpus spp.) (Tenuipalpidae) are major pests of great agronomical impor-

164 Maria Navajas et al. / BioRisk 4(1): 149-192 (2010)

tance because of their broad host range, worldwide distribution and economic impact
(CAB-International 1986, Fan and Petit 1998, Gerson 1992, Heungens 1986, Natara-
jan 1988, Parker and Gerson 1994, Raemaekers 2001). The most important threat for
Brevipalpus spp. is the spread of citrus viruses (Childers et al. 2003b).

Among parasitic mites, the hair mites (muskrat mites) are currently considered
non-pathogenic for humans although they are sometimes found in the fur of other
mammals. Laelaps echidninus (Laelapidae) is a common worldwide ectoparasite of the
spiny rats (hystricognath rodents), wild brown rat and is occasionally found on the
house mouse, cotton rat and other rodents. It is a bloodsucking mite and the natu-
ral vector of Hepatozoon muris Balf. (Protozoa, Adeleidae), a haemogregarine parasite
pathogenic for white rats (Smith et al. 2007) but which should not be overlooked as
a possible vector of disease to humans (Wharton and Hansell 1957). Ornithonyssus
bacoti (Macronyssidae) is a parasite of rats and inhabits the area in and around the
rat’s nesting area. This mite is the only one of the common rat mites which frequently
deserts domestic rats to bite man or his domestic and laboratory animals (Cole et al.
2005). It is also a bloodsucking mite and its bite is painful and causes skin irritation,
itching and skin dermatitis in humans (James 2005). Ornithonyssus bacoti, is a known
vector of the murine filarial nematode Litomosoides carinii Travasaos. In addition, it
is susceptible to the transmission of endemic typhus, Rickettsia typhi (Wolbach and
Todd) 1943 (= R. mooseri Monteiro) to humans (Berggren 2005, Bowman et al. 2003).

Epidermoptes bilobatus (Epidermoptidae) is a bird parasite causing avian scabies.
This endoparasite burrows into the skin causing inflammation and itchiness. The skin
thickens with brownish-yellow scabs, which may become secondarily infected with a
fungus. It is difficult to control and can cause death. Culling infested birds is usually
required (Department of the Environment and Heritage 2006). Ornithonyssus bursa
(Macronyssidae) is an haematophagous natural parasite of common birds including
pigeons, starlings, sparrows, Indian mynahs, poultry, robin (Berggren 2005). These
pest mites and parasites are and will remain a long term problem for poultry housing
(Gjelstrup and Moller 1985). Although none of these two species of mites are truly
parasitic on humans and pets, they readily bite humans and are liable to cause allergies
and dermatitis in human (Denmark and Cromroy 2008, James 2005). Dermatopha-
goides evansi (Pyroglyphidae), and a species alien in Europe, Glycyphagus domesticus
(Glycyphagidae), have been accidentally introduced by humans and often encoun-
tered in synanthropic situations (Bigliocchi and Maroli 1995, Hughes 1976, Thind
and Clarke 2001). Glycyphagus domesticus also occurs in bird, bat and mammal nests.
It is associated with moist and humid conditions that promote the growth of mould
on which they feed (Thind and Clarke 2001). Dermatophagoides evansi (Pyroglyphi-
dae) feeds on detritus and is also found in house dust, birds’ nests and poultry houses
(Piotrowski 1990, Razowski 1997). Dermatophagoides evansi represents a source of air-
borne allergens in indoor house dust (Eriksson 1990, Musken et al. 2000) that may
cause sensitization, dermatitis, rhinopharyngitis and asthma especially among farmers.

The honeybee ectoparasite Varroa destructor causes serious losses through feeding
injury in apiaries in Europe but also almost worldwide. While the populations of the

Mites and ticks (Acari). Chapter 7.4: 165

Figure 7.4.7. Ixodidae ticks on tortoises and snakes. a Hyalomma aegyptium on tortoise b Amblyomma

exornatum semi-engorged on Python head ¢ Amblyomma sp. on snake head (Credits: Nicasio Brotons)
d Female of Varroa destructor on abdomen of Apis mellifera (Credit: Alain Migeon).

parasite reach only a small size within colonies of A. cerana and do not damage the col-
ony, infested A. mellifera colonies die. The problems with varroa control are typical of
those encountered in curbing arthropod pest population. Varroas are becoming resist-
ant to the acaricides used by beekeepers to control them. ‘The recent discovery in several
parts of the world (notably the United States of America (Harbo and Harris 2005) and
Europe (Le Conte et al. 2007)) of honeybee bee colonies able to tolerate heavy infesta-
tions of V. destructor opens the door to lasting solutions for controlling the parasite.

A positive impact is recognized for the three mite species deliberately introduced
to Europe for biological control of house flies and tetranychid mites. Phytoseiulus per-
similis and N. californicus are two well-known biological control agents used against
spiders mites such as Tetranychus urticae Koch (Garcia Mari and Gonzalez-Zamora
1999, Helle and Sabelis 1985) and Phytonemus pallidus (Banks) (James 2005). The
third introduced mite, [phiseius degenerans, targets numerous species of thrips (van
Houten and van Stratum 1993, van Houten and van Stratum 1995), e.g. Thrips tabaci
Lindeman and Frankliniella occidentalis (Pergande) (Albajes et al. 1999, Bartlett 1992,
McMurtry and Croft 1997, Sengonca et al. 2004).

7.4.8.Alien tick species: case studies

It is difficult to ascertain if a tick may have permanent populations outside of its native
range or, to the contrary, they are just isolated records. In some cases, a few examples

166 Maria Navajas et al. / BioRisk 4(1): 149-192 (2010)

of a given species have been reported for a small area or found over non-resident hosts.
This may result from the introduction of a few specimens, commonly immature stages.
The most important means of introduction and expansion of ticks (provided that suit-
able climate and host is available) is by means of engorged females, because of their
huge potential to lay thousands of eggs.

The movements of domestic ungulates have introduced some tick species, that may
be considered to produce permanent and viable populations out of their native range.
An example is the introduction of Hyalomma dromedarii into the Canary Islands, by
the importation of dromedaries (Camelus bactrianus L.). The native range of this tick is
northern Africa where C. bactrianus is the main adult host, and H. dromedarii is abun-
dant in wide areas of Mauritania and Morocco. The current population of dromedaries
in the Canary Islands was introduced from Morocco at the end of 18" Century, and it
seems that this tick came into these islands using dromedary hosts. H. dromedarii may
use a wide range of hosts in immature stages, thus increasing risk of spread and perma-
nent establishment (Apanaskevich and Horak 2008, Apanaskevich et al. 2008). It is dif-
ficult, however, to assess the reliability of records of Hyalomma anatolicum excavatum.
A recent review of the original two subspecies (1. a. anatolicum and H. a. excavatum),
concluded that they should be considered as separate species, although the matter is
hard to decide as both taxa have a well defined allopatric range (Apanaskevich 2003).
H.. excavatum is restricted to central and eastern Asia and H. anatolicum colonizes wide
areas of northern Africa. The records of H. excavatum from Bulgaria, Albania, Greece,
and Italy should be cautiously treated, as they may probably represent H. anatolicum
imported from northern Africa with domestic ungulates, as is the case for Hyalomma
detritum. The formerly recognized species H. detritum, restricted to northern Africa, is
now considered to be a synonym of the European H. scupense, which occurs not only in
scattered localities of mainland Europe but is present in wide areas of northern Africa.
Similarly, caution should be also applied for the single record of Hyalomma truncatum
in the Canary islands. This tick is currently known to be restricted to parts of Asia,
while a close species, H. rufipes, is common in sub-saharan Africa. While the adults of
H. rufipes feed on a variety of hosts, including domestic ungulates, the immature stages
commonly attach to diverse passerine birds. Most of these birds perform long distance
travel in their migratory flights from Africa to Europe, and they have been found car-
rying hundreds of immature ticks (Hoogstraal 1956). However, as mentioned above, it
is difficult for a population of nymphs to produce a viable and permanent population
of resident ticks. To our knowledge, H. rufipes has been recorded only in Cyprus and
Macedonia (Apanaskevich and Horak 2008), and we still do not know if these are per-
manent populations or only accidental records on their passerine hosts on migration
to lower latitudes from sub-saharan Africa.

The scenario for the tortoise tick, Hyalomma aegyptium, is however different. Its
presence outside northern Africa has been reported in countries such as Romania,
Spain, Italy, Greece, Bulgaria, Croatia, and even farther north in Belgium (Siroky Pet
al. 2007). The tick has permanent populations in areas of southern Russia (Robbins et
al. 1998). There have been also introductions of this tick by tortoises imported form

Mites and ticks (Acari). Chapter 7.4: 167

northern Africa or eastern Europe, where this tick is common. The only record of a
permanent population of H. aegyptium as a consequence of an accidental importation
recorded for eastern Spain (Broténs and Estrada-Pefa 2004). Since the ticks attach
to portions of the neck and legs of the host body, it may be difficult to find feeding
stages even after careful observation of the hosts. In the reported case of introduction
of several specimens of Testudo graeca infested by ticks, the hosts were kept in a large
private garden with a Mediterranean-type climate and vegetation. After some years of
recurrent tick parasitism in the tortoises without new importations and repeated treat-
ments, it was realized that the tick had permanent populations in the garden, and the
hosts became infested according to the seasonal activity of the ticks.

An interesting case of tick introduction into mainland Europa are ticks commonly
found on snakes, like Amblyomma latum and A. exornatum (both formerly in the genus
Aponomma). These ticks feed for a long period on the host, and owing to their small
size and preference to feed under host scales, they are commonly unrecognized while
importing a host out of its native range. Amblyomma latum is a very common parasite
of Python spp., which is becoming increasingly popular as a pet in Europe. The only
known case of an importation of A. exornatum was noticed on specimens of Vara-
nus niloticus that arrived into Spain (Estrada-Pefa (Unpubl.)). These imported ticks
founded a permanent population in the terrarium where the lizards live, under suitable
conditions of high relative humidity and controlled temperature.

A very peculiar case of tick introduction is an alien in Europe, the brown dog tick,
Rhipicephalus sanguineus. While feeding on domestic dogs, this tick is endophilic and
is normally restricted to the Mediterranean region, being abundant in kennels, human
constructions and private gardens where dogs remain unprotected against tick bites.
Because of its endophilic behaviour, this tick may survive independently of prevailing
environmental conditions, since human habitations buffer harsh climate. Therefore,
unprotected pets travelling may harbor feeding ticks, and introduce them to unin-
fested areas which might be far from their native range. Such cases of introduction have
been commonly recorded in the United Kingdom and northern European countries
(Garben et al. 1980, Sibomana et al. 1986), as well as in Czech Republic (Cerny 1985).
Although there are as yet no reports of its establishment outdoors, this tick could be-
come established out of its former native range as a consequence of global warming.

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Siroky P, Petrzelkova KJ, Kamler M, Mihalca A, Modry D (2007) Hyalomma aegyptium as
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Mites and ticks (Acari). Chapter 7.4: 177

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Maria Navajas et al./ BioRisk 4(1): 149-192 (2010)

178

Su ‘OU

€IX “AW ‘NT “AD ISI (1681
(8861) piAouRIAg| wida4 su“jdn{| “TIX ‘TI ‘Il | ‘ZO “Dg “AG! Dd ‘C061 yInog eIsy snoseydov{yg| VW ‘edaeN) aula visa
vO Ip
viuogvyy
‘prusofyvs ISIN TS6I FHS
(8661) 9laourieg SIAdg4ag EX ZI WT |SH“S661 yInos vIsy snoseydov{yg| Vv SULIQLAGIIVI VIII
(4661) snaps POLIOuy
p1AoUrIDg ‘(Q8G6T) PAoUrIAg SIUNIN’) CTX “VTX SU] SU ‘T861 YON snoseydoukyg V 196 [ FOFIOMY 1stahg DIAIIY
DY Of[ISIUALAD
DISOLQUILT
phgovssopisd vOLIOUyy 6S6I1 “UOSTIA
(6661) 91AouRIDg visoaquy| (H{-T{)f SU! SU ‘6661 YON snoseydov{yg| V IVISOLQULD DLA
(6661) vOLIOUy 661 FFP
SIAOyURIg pur W1A0URIIg | xay Blapaz] Bila ard | C3) SHY ZG. YON snoseydouvyg| V avLapay SNIVILAVIP
(€00Z) ‘Te 39 01939 (COGT “UuRYy 29
2912q “(600Z) veedomy euney Dyan’) ZI Sa <LI) LI ‘€861 eISy snoseydovyg} Vv WEN) avags YyGdvoy
seprdydorry
QLBT “eIfOATY
(SOOZ) PAAMASET] pue PAorag snypUD) {‘T ZO| ZO ‘8¥6L |Teordosy -eisy| soyepordjonysered| oy | smavqopiq soadowsopidq
‘ sepndounspidy
996 T'se3red
(Z007Z) eeOLIOUIY SUDSDAIPUNSIU
eydny ‘(dard ul) praoueiag | opunsau sap 1X ZI SY ‘NH! NH ‘0961 YON snoseydoudyg| 5 snadoqhydvoukgy
VALIDI XIVS
‘DLIYIUVAIVUL C861 80g
sng4ane) ISI 19 “ADYS 7UvLUVsSYpEVG
(FOOT) prAoURIOg ‘snuly) LLX ‘ZI SU! SU ‘Z00Z yInog eIsy snoseydoukyg| Vv sngdoqhgdourgy
sepridormopndiq

SIDUDIIFIY

venqeH

sorsjuno0s
popeauy

adoimy ur
Prosar IST

aSuvi sANeN

snjejsg

‘(IJ x1puaddy 928) SIN] 0} Jojor suonerAdiqge ieigey ‘(| x1ipuaddy 92s) 991 ¢€ OST
0] JajoI suoTIeIAdIgqe sspoo AUN’) ‘sa1deds stuasoidAID :-_ ‘adorny 01 uarpy zy :snqeig ‘adorn 0} uarye soiads aiTUT ay) JO soMsTIoIeIeYS pur IST] “|p zZ BIqUL

17a)

Mites and ticks (Acari). Chapter 7.4:

(L661)
OTT oq pur exdry “(Z007)
eydny “(Z661) pourra SOUL OUEAL PONOWY “(6S6I1 FF! 3)
‘(€661) PHAOURIAY “eITeIT LUNE VISAS) ase SU SLI ‘AH SU €661 YON snoseydouyg| Vv anisipas sdongy
(Z00Z) Pyssezesisg-PloiscE
‘uazuepdjaqny pun usforpeys vOLIOWYy TL6 I FHA]
‘uaIsyon. “uaTTyeq eypsinaq VIG ISNT raat qD Ws “AC! Ud ‘£007 yinosg snoseydouvyg| Vv avisyan sdojnoy
POLOWy (P68T ‘edayTen)
OMe ZOE OVC ALG YON snoseydovyg| Vv sngataqoyy sdojnoy
(€06T) Su “AW ‘NT NN (0681 “edo[eN)
JONOIT, (9661) P1ACURIDg suvjon{ C1X ‘P45 “7D “DG! SU ‘EO6I yInog eIsy snoseydovyg| Vv VIVIAISIAI VIII
Id “AW “OIS
(S261) Eh M¥Sah1 (LE6I
JIAISEUIOT, pur PIAOYsN{Iy SNAIE") CISel ‘LI ‘UD ‘SA} LI “pZT é PIS snoseydouyq| Vv ‘BUIMY) 2U0PaYs VILA
wunryoynedey
wmuosdjog
‘Tuo suyol
‘dss t1sejsnop vOLOWy COG6I TOFION
(E861) ‘Je 39 QIAouPIOg wmnuosdjog (F-ID [ SU! SU ‘T861 Yon snoseydoukyg| Vv ISUIYIIVNDS VIII
(Z00Z) PANY ‘(6661) ase]
PIAOYULIS PUL JIAOUPIOY ‘CITEI] OW ueouessoy C76 “edayeN
euney ‘(600Z) voedomny euney eSultAsS LIX ‘ZI ‘AH ‘AD ‘Id! LI ‘661 -Ipey snoseydouyg| Vv apnaounjad VILA
(6007)
voedoing rune ‘(8007) POLOWYy (TSG6I FOF1OM)
‘Je 19 TyTuoIaA-nouseuy| ‘ds snyiueiq oolf UD “Td {LI} UD ‘Z861 YON snoseydouyg| Vv 1gquvipylnd visa
(ZO0Z) ‘Te 39 Z2UNN Za[PZU0r) SnULY 09s Sd ‘Ld eOLOUy (6€61 FJ!)
‘(600Z) voedommy euney vavuly I ‘JIS-LI UD| SA ‘8661 YON snoseydouyg| Vv IVADUNIOIU VILA
(€OOZ) ‘Je I9 SIANTAY (8661) | “ds wensgsns7T
rysmourqeyT pure eyl0S “(866]) “untyofijvao SW POLOWy (€F¥GI FFIOyM)
plAouriag “(/661) PAouriog wnsIsnsIT | 1X “AAI “Td ‘OH “Ad| SU ‘S66I YON snoseydouyg| Vy 2AASNDY] VIsaIy
saimunos =| adorn ut sated
SdIUIIIFIY SSOP] WwIIQGeyY popeauy] prosel IsT | oSues oaneNy UIISIY snje1¢9 Ayrure,y

Maria Navajas et al./ BioRisk 4(1): 149-192 (2010)

180

(6661) PHAoyurIS
pure 91A0ouriag (2661)

HAourIaY “(8661) OMPIIV vauodvl EOC Sh61 FFP
op vorxojoredoi,y ug easy vYaUy’) OOLL ‘ZI AW ‘SA! AW ‘0661 YON snoseydovyg| VW IVYJAWDI SNIVIASO’)
DULNIOD
smo)
(6661) PIZZOT pue ‘DUuvTaav POLIOWy (GEG6T FFM)
puouresry ‘(g861) 7Aourleg smMoy| €1X ‘Ad ‘TL | AW ‘SU ‘LI| SU ‘1861 YHON| —_—_snoseydordyg| oy | __ surecesuerp vp hy dosdor
(F002)
JIAOULIAY (6661) FJsmoueqey] | ws021013 va9Inx POLIOWy (SGI Fofloy) 2uossapuay
“(COOZ) ‘Je 29 SEyopuaaryy | “vonvjs va9Inx Lf ‘ooll Ta “SM | SH GE yon snoseydov{yg| Vv sisdohg dop1say
SAPLOUOULIOD
VIUOULAAYT
(6661) ‘DILISAULOD POLIOWy 906 oe
SIAOYURIG pue IIAOUEIAg X SVN C1X SU] SU ‘1661 yon snoseydoutyg| Vv avyofyvut sakydop1sa)
UNULNGLA
‘wunssdvy Td (0681 “US2I5))
(6007) voedoing euney VII) ZI] TT AE Sa | SLI ES61 eIsSy snoseydouvyg| V SNIDUILVI SNAVIVIV
unuy
(L661) 91AouURIDg | -nssadsuom y vOLIOWy C161 SSHISpopy
‘(SOQOZ) ‘Te 29 Epapuaaryy | wnuqna sap CIX SH | SH 6 S61 YON snoseydoiyg| y | syvuorgisuvss saadosoqupy
HISHETEG LD EOMOUYy EVGI THY
(6661) B1Zz0T pue nuowresry| ‘szaavy sn) qi ‘ZI LI] LI ‘1661 YON snoseydouv{yg| VW vssopyaund sados0qqupy
(Z00Z) | ‘ds wnagsnsrT
eydry (6661) p1A0yueIS| ~~‘ wenyofyvao POLOWy SC6I
pure 91Aouri2g ‘erely euNey wnsisnstT| CIX ‘LIX TW Me ak SoG YON snoseydovyg| Vv JOON Lgsnsy snjngpy
sousaja XYVS eOLIOWYy (2561 S9F12M)
eyeyeuney) = vaqye xyPS| €TX ‘TIX LI ‘QH| NH ‘2661 YON snoseydoyg| Vv sisuapoys sdoynay
LW
“AW ‘DISSLI
(S261) UVS:LI (6S61 yy)
PAageUOy, pur prAoysniry ea) €1X‘T LI UD “SA| UD “8S61 RIS snoseydoutyg|} Vy sssvyaqad sdojnay
samjunos =| adoimy ur satad
SdIUIIIFIY s}sOP] WeIIQGeyY popeauy =| proses ysT | oSues oaneyy sWIsaY snqe3¢ Ayrure,y

181

STJDAISND S14]3")

C6 | ‘ueLesepseg

Mites and ticks (Acari). Chapter 7.4:

DIVISVINDI
(Z661) ‘Je 39 pIAouPRIOg S19) CTX “1 SY SSW! SY ‘S661 PIUsWIY snoseydoudyg V S19JII DIJIYIIT
(SOOZ) PIANIGET PUe PAOIZDG IN ‘LI FOG “eda[eN
‘(600Z) voedoiny euney | wo“puapopogy 2) c° (6 AB ED CUMEAS ATS seq -eISy snoseydoiv{yg| Vv avaqvzv sadosoy hg
snxapfodqad
‘py ‘Ssnqwrtanu POLIOUIy (ZIGI ‘40D)
(C861) Jew iaouriog) sagzummupy) (F{-Tf{) [ Sul SU‘I86I yinos snoseydov{yg| Vv 1gjuvivup saydoz0pjG
UNI Of1LOUL OFG I FOAM
(6661) 2Ao0yuRIS pue unuLay4 POMOWy TULA IUDSMAGI
p1AourIdg ‘(/66[) PAURIOg -uvshtg)| OOT{STX SY! SU ‘Z66I1 YON snoseydov4yg| Vv sngdoqhydviny
NA ‘IS “AS
‘NY “OU ‘Ld
“Td ‘ON “IN
“LW SIN
‘AW ‘AT ‘IT
“al ‘OH “UH
PSRs eet ed)
UD “AD ‘Us
‘Td ‘SA “Md
(€OG61) MOLL, “Ad “ZO AO
“(SS6L) 2H4°3S1ZPPH “(6002) umyd ‘HO ‘Dd (L¢gT ‘Joypoasusse,)
voedoiny euney ‘(¢¢61) 199g ‘ajdde seag I “Ad ‘Vd ‘LV! AW ‘€06I | oruesoidAry snoseydouvkyg| 5 wkd satg dora
VIUSAULOP ET
QUVILAIUD Cf
(Z861) prAcfoatiqog pue VIDUIBADULA vOLIOWy 6E6 1 IFO
p1AourIIg ‘(/66[) PAOURIDg snuntg| T)ETX T Su! SU ‘8Z61 YON snoseydouyg| Vv avipursivuia sahg dow
(€66[) iAouriIag SUPATALIGUAS 6€6 I FFlOyy
(O86) ‘Je 19 zoraINsy snssadn’y ZI AW Al AW ‘9861 seTUIOJIe) snoseydoukyg| 5 issaadna snaawuiagidy
saimunos =| adorn ut stad
SOIUIIIFIY SSOP] WweIUIQGeyY popeauy =| proser ysT | oSues oaneNy WISI snjqe1¢9 Ayrure,y

Maria Navajas et al./ BioRisk 4(1): 149-192 (2010)

182

(Z00Z) ‘Te 39d AfOrIS AY ‘OU ‘Ld
‘(ZT61) 2Z[NYIS “(866T) Te 19 ‘LI “AWOAUD
surqqoy “(TT61) wurumnay (YY ]40g OMA aa.
‘(S961) J9PIPd “(002) yUUsUe ) ‘Sd “Ad ‘AO (8SZT “T)
eUudg-epensy pur sugioig SOSTOIIOT, I ‘yg “Ad “TV! AC ‘TIGI voy | soyepoidjonisered| vy uniydsay vULULojvdEy
(aseastp ourA] POLIOUY (TZ81 ‘Aes)
yursues1) 8oq Dy yal wa% YON | sJoreposdjonisered| vy SYIQUIADA LOJUaIvULLA]
uolAyd PHS “Yooy
(Tqndup)) eusg-epensy ‘gqnday a Sa! Sa ‘F007 voy | rorepoidjonisesreg) y UINIVULOXA DULUOKI QUILT
(7002) Teag bYST Woy
eudg-epensy pur sugioig ‘gqnday d Sa! SA ‘F007 voy | Joyepoidjonmisered| vy unqiy)] DUUOlquy
depIpoxy]
(6661) UNAGNA
rysmourqeyT pure exlosg ‘(796[) ‘py snuvyyd
sredny pur oxuayo1sys -opnasd y
‘(L00Z) PIANT (6661) | Wenuzevqaons Td EO LO UUKE GST Aas,
PIAOYULIG PUL PIAOULIOg Hy! — FATI ‘Su ‘AT ‘NH| AT ‘ZS61 YON snoseydoiyg| Vy sapadiapunb saws,
(4661) OjfFT oq pur eydry vy of1qsnsUD O7X POLOUIY (SE6T TOFIOM)
‘(Z00Z) eydny ‘erpeay euney SNUIXDLT | “ELX-OTX ‘ZI LI ‘NH! LI ‘8861 yMON snoseydovyg| Vv quixvdf{yvs sng dojosay
UNI4IUISGV
DISIULIIAPT
‘qvuroyfo
WNIVXVAVT. (F96T
(6661) « SHSODIAIS vOLIOWy ‘SIARC]) SUBLSVALLADILA
PIAOULIC pu DIAOURIOg uosas14g| (F{-T{) [ SU! SU ‘6861 YON snoseydovtyg| VY pyjayuayoqaays
alqsaqupo
Wn IUsofIvI
‘TRA OPUNSIU (CLG L‘SSryspop)
‘V ‘opunsau vOLIOWY DSOIISIAILG
(dord ut) prsouriag Hay) YTX ‘TIX SU “Id ‘NH SU ‘6661 qON snoseydouyg) V mjjaquaqo4iaags
samjunos =| adoimy ut satads
SdUIIIFOY SSOP] Wwyqey popeauy =| proser jsT | oSues oaneN auIZay snyei¢ Ayrare,y

183

Mites and ticks (Acari). Chapter 7.4:

(Z00Z) FPUY AN
“(SO0Z) ByANIseT pue PAOIJOS
“(1861) JoyeUY AM pure oneg

yerysnuUy

L

ZO ‘SS6I

POLIOWy

YON

royepoid jomisered

PYOL ‘PIOFPeY

SNUDILAIULD SNLOG COAISLT

(S007) PYAMGET] Pur PAoyas

yeIysny]

rie;

ZO ‘SS6I

eOLIOWy

YON

royepoid jomisered

seplsoydonsry]
(6061
‘syueg) susourdsiynu

sdvjavjviqppuc

(ZS6T) [esueH pue
uoeyA\ “(Z007Z) ‘Te 39 YUU
(SOOT) PYAMASET Pure PAOYJaS

yer Autds

ZO ‘SS6I

jeordouy, -eisy

royepoidomisered

L88I ‘asapog
snurupigza sdvjavT
oepideyae]

(JOAoF

o1seiI0WdeY

osu05

UedUTI)

yWursued)

sueumny

Ayfeuorses50
‘ssoyospoy LIGL ‘eaourryedjoyy
‘sjeuTue 2Q AOWTYLA SMIISS04
(S961) pry onsawmoq | LF ‘oq ‘CA ‘bd Ow! OW ‘S961 | PUesoidday| sOrepasdjorsered| Vy snyvgdandigy
NVO YV81 YON
(9C61) Jeenssoop] ge) | Z4 ‘Od ‘CA “ba NVO-SH| -SA9S6L | ofueSoiddry| soieposdyonisesred| vy UNIVIUNA DULULOTDAET

LI “AeO
(0961) ‘Te 9 Appisoy UD UD

“(SS6IL) Fysueiq ‘(ZZ61) ‘Je 29 ‘NVO-SA OGG] AssUPIOWIOT
Tyjoueg ‘(€QOT) yoracyseuedy ue) | ZF ‘94 ‘SA ‘PT | AD DA“TV! = OFGI otuasoiddry| sroveposdorsered| -y ULNIVAVIXA DULULOIDAET
(6761) 2049S VV81 YON
pure ozjnyosg ate C61) rysusIqd spoue,) | /4 “OF “CH “ba | NVO-SH “Dd 6761 POLY royepoid orsered V IAD PIULOAp DULULOJDAET
(6761) FYVOTYIS pur DESI yoy
azINyys ‘(€QOT) Yorasyseuedy sey | Z4 ‘Od ‘CA “ba RO! AD ‘6Z6I | 2uesoidAry| sJoxepoidjomisered| vy UNIYOIVUD DULULOJVAFT
samunos =| adorn ut satad¢
SOIUIIIFIY SSOP] WwIIQGeyY poprauy] prosel IsT | oSues oaneNy WISI snjqe1¢9 Ayrure,y

Maria Navajas et al./ BioRisk 4(1): 149-192 (2010)

184

POLIO

GEG Foy] Sumssvaruyy

(doid ut) raouriag | vsoursnys snurpy ID Su} SU ‘Z00Z YON snoseydouk4yg| Vv sngdoqyhgdpssats
Bote CU 9961 fly
(‘dasd ut) p1aouriag| suqouss snug | TTX ‘GTX AED SU} SU ‘S007 YON s| VW snaigosss snqdoqas
EV6L THY
(SOOT) [e229 9Eyepucaryry | xwyaqy wlapazy aie aera | Su ‘Z00T | POLY YyINos snoseydoukyg momsapay sngdoylg
sepndowyg
(ZO07) 7G ‘(S007) 8961
BYANISLT PUL PAOIJIS vOLOWy JOMNOY 29 snyodsoyN’T
“(T861) JoyeUY\M pure Joneg IeIASNY] Tek Z)| ZO ‘¥007 YON | sJoreposdjorisered| y avuppuo sardosolyy
seprdoso04jy
(S007) sow
($861) F]9W pure dnasjals
(8007) AorWIOIZ pure speuUrU eu POLOUy (asaytog)
yreurusq ‘(GQ0Z) uerssiog ‘sprig (1D MC ‘ZO! ZD ‘8P61 S29D| Jopoidyonisered| y SANG SNSSMUOGIIUAC)
(ZO0Z) J°PUYM
“(S00Z) ByADAgET pure PAorjag
‘(SO0Z) some (8007) ‘Je I9| sUepos sp4y
yoorqisise’y “(CQOZ) ‘Te 9 “‘soOTUr “eI (C16 SII)
3]07) ‘(€QOT) ‘Jeo ueUIMog| ‘Tes Jeordon (TD Z| ZOD ‘TS6L | feordory, -eisy| soiepoidyonisesred| oy 090g SNSsUOYIIULE)
sepIssAUOIIE|A]
(ZO0Z) 2957PUYA‘(S007)
eYANISE'T PUL PAOIJIG vOLIOWYy OIGI ‘syurg
“(T861) JoyeUYM, pure Joneg qerysnu ie) Z)| ZO ‘v007 YON | sJorepesdjorisered| y snpyva snsogdossstyT
(ZO0Z) 2>7PUY A ‘(S007)
eYAMISE'T PUL PAOIIG vOLIOWYy ZTL6I “euruIqng
“(L861) JoyeUY YM, pure Joneg qesrysnu Te Z)| ZO “F007 YON | sJoreposdjonisered| y utp snsogdosgstT
(ZO0Z) 2>7PUYA‘(S007)
eYAMISE'T Pure PAOIZIG vOLIOWy HOGI ‘PIOJp2y
“(T861) JoyeUY YM, pue Joneg qerysnu ieee Z)| ZD ‘F007 YON | sJoreposdjorisered| vy 14aizop snsoydosgstyT
sorunos =| adorn ut sated
S9dUIIIJOY s1SOP] Wegqey popeauy =| proser ysT | oSues oaneNy JWIIS2Y sn}e1¢ Ayrore,y

185

Mites and ticks (Acari). Chapter 7.4:

(1007)
oyre) pue pulyy, ‘(Z661)
FysMmozEY “(YG6G61) PISMONOTY
(0002) ‘Te 39 weysNY “(9Z6T)
soysny] “(0661) YOssyLY
“(S6G6I) HOIeW pur ryoorsig

asnp 9snoy

AT
“Td ‘ON “IN

umouxuy)

POLIO

YON

royepoid omisered

LOGI “UOIsuyo[

19 saysny ‘ure ssuvaa
saprosvy doyvuLsaq’

aeprydAysos
VIVINIVLAAS
SNUNAT
saprouviyyd O9G6I UlalsuTe/
(666 |) BIZzO'T] pue nuowesny lay I LI) LI‘I661 | 2resoiddry snoseydouyg| Vv sadtumnbs snuojso,y day,
(SOOT) PYAMISET pure PAOIfIS
‘(Z661) YOID pue Anmyp
(S861) SHoqes pure a[[9H
‘(66G61) Plowe7-zayezuor)
pue weyy Prorer) “(70 0Z) (YS6I1
Oddi ‘(966T1) YOorgseasey sngahuvagay LI POMOUy TOSI) snsusofyvs
‘(Q661) Je 39 YOD Jo JOepol I “qd ZOD ‘Dd! GD ‘1661 YON | sJoreposdjonisered| vy (snjniasoany) sniastquy
(SOOT) PYAMISYT pure PAOIIS
‘(Z661) YOD pur Anmyp
(S861) SHeqes pure [9H
‘(666[) Plowe7-zayezuor) pure
HRY PIED “(Z007) Odd A
‘(9661) YOoIgsIeIsey ‘(8661) sngahuvagay “qy ‘Sq “Ad POLOWy ZSG6[ OMUaL-seryly
ye 19 YOID (7661) HIeg| —- Jo JOYeparg I “Ad ‘ZO ‘Dd! ZO‘'PL6I ymosg| sorepesdorusered| vy sytussad snintasoqhg gy
sepriasoyAy
DUDIULOALA
snaadiun{
‘VdAVIOAIVUL
snssasdn’y
(ZOOZ) | ‘Sesuaveqoou *)
Je 19 YIMUIS “(900Z) peasjeH]| vuuviuosmy vOLOUryy LL6I “yATUS
pure rysmozieis-eloiscg | ‘snuvddoaupy’y ral qD))| 7007 YON snoseydouyg| Vv LUV AMIOVULVYI SNIVIISIAT
saimunos =| adorn ut sated
SOIUIIIFIY SSOP] WwIIQGeyY popeauy =| proses ysT | oSues oaneyy WISI snjqe1¢9 Ayrure,y

Maria Navajas et al./ BioRisk 4(1): 149-192 (2010)

186

WN ‘Ld

“TNA a) Ponoury: (Z98I [eAnpstog)
(8Z61) yeurueq SBIdEIED) oorf Ud “AC “Ad) Ua ‘2981 SRO snoseydoiyg| V snynssnd sndjodiaadg
vn ‘Ou
(L961) YosuR BUTT OS aL a
‘(S00Z) ‘Te 39 9Ppepuaar[yH DyAuay ‘AO “WH ‘Dd
“(G€00Z) “Te sEPTIYD ‘vaffor) ‘Va Ad ‘SU
“(8€007) ‘Te 39 SIEPTIYD Bie) dS “IN “TI POneUly CZ8I ‘narpeuuod
‘(986[) Jeuoneuinuy-qya SNAIL) Z] “Ad ‘UA ‘IV! 9861 ‘LI YON snoseydoi4yg| V snypaogo sndpdiaaag
SHUNAT
‘x1UaOY NIL]
SWINAISNSTT
‘XAT SNISIQIET
‘VIUAPAVE)
(E007) ‘TE 9 SIOPTFYO ‘SnedT) "IN (GE6I syste)
“(BCQQZ) ‘Je 29 sIOppIyD| ‘snoseyddjog OO { ‘ZI TT MS) ‘Sa S66 SEI jeordosy, snoseydovyg| Vv ssatuaogd sndjvdiaag
syequsureUusIO OU POMOUy (6P6[ JOSaITP1)
(2€002) Te 39 stepTYO ‘smn OOTL ZI | UD “Ud ‘OG ) wrouyuy WION| _ snoseydordyg) Vv sumap sHapndiaaig
LE Lasts
(E007) ‘Te 29 SIOPITYD aide adds <LI “UVS-LI
‘(PEQOT) ‘Te 19 SJOpTTYD VIJGUD) ‘LI YD “AMO POLOWy (FOGT ‘syueg)
‘(98G61) [euUOneuUIaIUT-qyD ‘SNAW) OOrf ‘ZI XD YA ‘AOD! 8661 ‘LI yon snoseydoukyg| Vv snatusofyvs sndypdiaag
sepidyedmuay,
(1002)
SIDYIeUIIeY ‘(F66[) UOStd+) SIAPI] aC]
pur Joyieg ‘(886) uefereieyy pure simaj “Ad ‘Su ‘OU
‘(9861) suasunayy “(Z7661)| — ‘saqquaedaa “IN ‘OIS-LI
WOSIS) “(866T) 1Aq pue uej ‘sdor9 UVS-LI “LI FOG ‘syueg) 6127
‘(986[) [euOneUIAUT-qy7| :snoseyddjod I ‘dq ‘Sa ‘NA| S961 ‘LI eyUr'T LS snoseydouyg| Vy snuauosavqosvg Mog
seprumouossey,

SIOUDIIFIY

veyqeH

sorsjun0s
popeauy

adoimy ur
proser 3ST

aSuvi sANeN

snjejsg

187

Mites and ticks (Acari). Chapter 7.4:

Sol
SISUIULYI ayerodursy, ‘Toyeg 29 preyouig
(0661) UessoqIoTA, snaadiun{ rel IN| IN ‘0661 -eISV snoseydovyg| Vy sngypsad sngauosyC
(S661) vOHOUYy CIGT ‘SPAory
"Te 19 Z0GOq ‘(F9G6T) 42z200g XULDT ZI Td| Id ‘P9G6T YON snoseydoudyg| v s11Avy sngauosyc
vYaUD’)
‘Uospuapopoygy ajejoduoy, (ZIG J089I2)9/1)
(4861) tyserg pur v0y vayvzy ZI IN ‘LI| .LI ‘S861 -PISy snoseydov{yg| Vv s1yt sng uosyC
DIUUISED) Ld ‘LI ‘Ors geoLOUTy (Yost ‘syurg)
(6661) PIZZ0T pue nuouresny | “qos snouanc) ZI -LI UVS-LI) LI ‘ZZ61 YON snoseydov{yg| VY L0j0I1g sng MUo0stIC)
(9€6I “UPTS)
(€OOT) ‘Te 39 BIOTer) SNAIL I Sa} SH ‘TOOT | [eordory-eisy snoseydovdyg| V sypquatso sngaubaaing
POLOWwy (PIGI TOSI)
(€QOT) ‘Je 39 BIOIeD SNAWD I Laesee | CaP LOZ SRD snoseydouvyg| Vv isyuvg sngmupéqajny
9S61
ayerodurdy, ‘uloIsuTeEN sngastoinf
(BZ61) tezog VIN '3) OH| OH ‘F461 -eISy snoseydov{yg| Vv sngnuvaqag hang
SS6l
POLIoWyy Tayeg 2Q preyouig
(€007) YORBIW “(OLGT) FeZ0G| _ SNOTAFTUOD ZI OH Wd} OH ‘0261 YON | —snoseydordyg) =v | sempy sngokunaaning
eOHeUry (C161 “ourmg)
(S002) ‘Te 3 PPfepueArT sudo I SU NIN “Iv| Su ‘7002 WHON| —_snoseydoudyg) Vv | jéoppem sngohumsesoy
av voLoUry (€P6T FOsoIDY])
(Z661) BUOUITED) | MIpLHr) ‘sn.HED I CVWGLd | Ld ‘0661 SRO] snoseydodyq| Suita STO UT Crt
seprydAuesay,
“O49
(L961) uosuryy ‘(CQOZ) ‘Te29| ‘sesdouavyvgg Su ‘OW POLOUy ChGI JOyeg
PPpPpuaary]sy “(896 |) Yreurusq ‘SPpIYDIO OOLf “TN ‘AD “Aq | Umouyue S299 snoseydov4yg| Vv snoyfiavd sndyvdinuay
id (PE8T se6nq)
(Z961) uosueyy SNAIL OOL{ ‘ZI ‘LI UD WA) umouyuy jeordoay, snoseydouyg| Vy snyppnvs sndvdinuay
samjunos =| adoimy ur satad
SOIUIIIFOY s}sOP] WwIIQGey popeauy =| proses ysT | oSues oaneyy sWIsaY snje1¢ Ayrure,y

Maria Navajas et al./ BioRisk 4(1): 149-192 (2010)

188

SC6T Joye

(F96T) eINeOI POLOuy 2Q preys snuaspupd
eysudzodory pue yoz0g ‘uopout’) I Td | ee tOG 1 YON snoseydoudyg| vy SNGIMUDAIAJOZ1GIS
(F00Z) ‘Je 39 UoasTYy ayerodurdy, LV6T Pay avsnquvg
‘(Z00Z) UoosTy pur iosny) sevooesnquieg ZI WA! Ws ‘1007 -eISV snoseydoukyg| Vy SNGIMUDAIAJ OZ1GIS
(€66T) abe BOT. (OS6I
"Je 19 solfnog-nouuvoredeg “VIAVOULT vOLIOUIY TOSI) 2uzdny
‘(OZ6T) SlToyrurze py “snuldnT I YD! UD ‘8961 YON snoseydouyg| Vv (vuigouvwjay ) pIgosay
(6861) UeS19qI1A “(S96T)
endde, ‘(€g6[) auroeA,
‘(8S61) JaIquiey “(0861)
p1Aouri2J ‘(6861) ‘[e 19 epueg
“(ES6T) PEAONSMLI “(SZ6T)
‘Je 19 uosddaf ‘([ g6]) o12aNy AA ‘VA
ap pure reyy Borer) *(600Z) ‘TS ‘OU ‘Ld
voedoimy vuney ‘(/861) “Td ‘ON “IN
stjnopedeg pue jonourwUury SW “OIS-LI
‘(6Z61) ‘Te 9 OTC ‘(866T) UVSALI ‘LI
pueg pur seysiD “(Z61) ‘AH ‘YH
e10y pur turoduwrery ‘(0/6T) UD “ATWO
rezog (8/61) Hapseg pur ‘UD “dD “WA
uruIMmog “(C66T) ‘Te 39 ‘Id ‘NVO-SA (9161 10821D9/\)
Tulusog ‘(/96T) Pysaeyeg SNAIL) Gi. LL ‘Sd “Dd “TV! UA ‘OSGI eIsy snoseydoukyg V 14419 sngououng
sngdiqvang
‘sumjont
‘snI4anQ) WOO oH (9761 SIH)
(8661) ‘Je 29 pueljog| :snoseyddjod rah YOO’! AA ‘8861 CRD snoseydouyg| Vv avniund sngnuosyc
(S661) ‘Te POLOWwYy (OSGI IOSAIZ)Y\)
19 ZOGO] ‘(F86T) eysuAzodory | “ugos snouanc) 3) Id! Td ‘F861 YON snoseydovyg| Vv mpavgniad sngouosyc
961 “OTP Reqqy
DUVILAIULD POLIOUYy 29 Jayeg ‘pany
(SOOT) ‘Je 39 JezeoTV pasha Il Sa! SA ‘F007 YON snoseydouyg| vy avassad sngmuosyc
samjunos =| adoimy ut sated
SOIUIIIFIY s}sOP] WeIIQGeyY popeauy =| proses ysT | oSues oaneNy sWIsaY snje1¢9 Ayrure,y

189

Mites and ticks (Acari). Chapter 7.4:

COL IOS: SS6l
PLOY ISSUT vOLOUyy Toyeg 29 preyouig
(9861) sloyruizepyy ‘SNINQUIDS I WD | UD ‘9861 YON snoseydoudyg| vy snpyapiung sng uvsgay
SnUNAT
‘uoshdolsy vOLOWwy ZOGT TCG
(F9G6T) 42200g STOEL I Td} Td ‘7961 YON snoseydoyg| V rwquss sngaundda]
aeaoeqe,] CC6I
‘SAID NVO ‘QIpuy sns1uoparpr0au
(6861) efuoiues pur inseisaj) :snoseydAjog I NVO-S | -SH ‘6861 jeordoay, snoseydouyg| Vv sngouvagay
“019 ‘snUu()
VIAVBULT
YlaNUuoT vOLOUry LEG] TOSaIN spy
(Z8G6T) JoIquiey “AIP ‘SULA I Ui) WA ‘1861 YON snoseydoukyg| Vv YaUppIu. sngauvssay
0961
19 ‘vaouLody NVOD ‘prey 29 Joyeg
(6861) ‘Je 39 spueg Vn I NVO-Sa ‘SA| -SH ‘686T | eordory-eisy snoseydoudyg| v 1AUDIAVJIDUL SNGIMUBAIAT
(9861) SHoyrurzey
(8961) syoyrurzepy VABUDAPNET L761 “ePIYysEy
‘Q66] ‘Je 10 duRP]| :ovaoeSerpIxes Oorf WD “Ad! UD 9961 | feordosy-eisy snoseydoudyg| v IWNVZUDY SNGIMUPAIIT
(2007) OSI “(00Z)
uoasty “(G66 1) PUOWITeD pur Ld ‘GVW
era] “(Z661) ‘Te 1 Mser9q Ld ‘Ld “LI 0961
(6661) OJApnosy pur insess97 WA ‘NVO-Sa POLOWy “‘preyouig 29 Joyeg
(9007) ‘Te 19 Yousesey | — seacvurfog) =X ‘OOI{I | “IVa-Sd ‘S| Ld ‘1661 SRO] —_snoseydoyq| Vv supa snqohunedey
snpluoryy Blavy
(F561) ua19H ‘(F96T) “vdOeSOY BO SUUN: (OS6I ‘10321D2/"\)
eysudzodory pur yoz0g| :snoseyddjog ral Td ‘NH! AH ‘FS6I YON snoseydoudyg| vy sisuapvuvs sngahuvasay
(€007) ‘Te
19 SION “(O00T) FYSMozIeIS
-e[01SC ‘(8661) ‘Je 19 purljog GTX “VTX ‘ETK IN ayerodurdy, LIGI ‘syueg
‘(Z00Z) UoosTPy pue josny) ovooesnqureg) ‘77X ‘TTX ‘I | ‘GD ‘YA “Ad! WA ‘S861 -eISV snoseydouyg| Vv snisvjas sisdoapusyy
saimunos =| adorn ut satad
S9IUIIIFIY s1sO}] WwIIQGeyY popeauy =| proser ysT | oSues oaneNy JUIIS2Yy snjqe1¢9 Ayrure,y

Maria Navajas et al./ BioRisk 4(1): 149-192 (2010)

190

MS ‘IS ‘NU
‘Su ‘OU ‘Ld
“Td “IN ‘(LW
(YI-DISS
UVSLI LI
‘aI ‘NH “UD
(Y86I) ey pur Jouny ‘aD ‘UOO
‘(€861) uany “(6Z61) Wd “UWA Td
SaaTEOUOT) pur asJoYy “(1861) ‘Sd “Ad “Md 000¢
ueuIMmog pur syIIr) ‘(7Q0Z) 2 | A al ‘ueWonIT 29 UOSIopuyy
Je 19 aA 2q “(Z86T) UJOD]| —aasesed 90q ( ‘q ‘AV “IV! SU PIGI eIsy| sJoiepoidonisered| vy LOJINAISAP DOLLY
deplore,
aeaoeqe,y
o10xa
“‘DAINUOT POTIOWYy CC6I ‘TOSIIN IY
(9861) syoyruIzieY DIAIUN J Sekai AYORNDYD WD! UD ‘T861 S29 snoseydouyg| Vv ysnk sngaupsgay
saimunos =| adorn ut satvad¢
SOIUIIIFAY s1sO}] WeIIGeY popeauy =| proses ysT | oSues caneNy JUNISIY snqe1¢9 ATrure,y

191

NA ‘SU

‘A MW “OIS-LI

UVS-LI “LI “UH
UD Wd ‘NVO jemepeid 9v61 Adpoq
(ZZ61) ‘Te 39 PPIOYT apes) {| -Sa ‘Sa ‘Dd ‘TV| umouyuaQ adoing /orisered asuadngs DULULOJDAET
eepIpoxl

(1002) 21D
pue puryy, “(Z661) PIS0z"Y “(066 1)

7 PYSMONIOL] “(000T) ‘Te 19 Uaysnyy ‘(9Z6T) AS “Td (SZZT 1995 9d)
x soysny ‘(S661) Hore pue ryssoTsig | snp sonop] Z{‘If| ‘ON ‘LI ‘Od Id} Umouyuy odomy snosoarnap | snougsauop snsvg doy
8 seprseyd AdAqx)
<a suadtasaduas Ta ST Ae UOTSaI (1681 ‘edeyeN)
S (8661) PHAouRIAY song | ¥TXTTX] “AA ‘ZO ‘DA ‘LV) SU ‘8661 | Uveueseupayy| snoseydorkyg| —-#zuzussauva sadgdotg
2 1X Yd sey (0681 ‘N9¥xP0J)
S elyeqy] euney snynasay SBO1ID| ‘OW ‘LI‘ZO ‘DA! ZO ‘ZO61 | uUeauvssoupoypy | snoseydoidyg tursspooddiy snjnay

ei €5‘Td ‘AT ET
ES “LI ‘NH “Wd “AG Ise (0681 ‘ede,eN)
8 (6007) voedoing euney epee LITX ‘Z1I| ‘AD ‘°ZO “DA ‘LV | OW ‘LOGI | URauvssoupopy | snoseydoidyg 1Nao] ViLaIy
= uinaUutonssal (7681 ed2TeN)
S (6661) P}A0yURIS pure d1AOURIIg | UoLpUuaspopoy gel SY SLI “ZOD SIV! ZD ‘TS6I sdiy snoseydoukyg stdqsadyy DILIIY
seprAydorg

Vn ‘NU “OU “Td

LI UD “dD “Ud
‘Sd “AC “Ad ‘ZO rorepaid (VOLT ‘snoHqed)
(6661) [yey pue jaineq IY ‘HO ‘Dg “Ad ‘LV /orisered snxayfas SBoLY
oepisesiy

adoinyq ut satoadg
SdIUIIIFOY sSOP] ,eugqey | sarunos papeayy | proses ysT | oSues aaryeNy Ayrure,y

‘({] x1puaddy 92s) SIN 0} J9J0I
suonerasiqge yeigqepy *(] xipuoddy 9208) 99 € OS] 02 JOFoI suOMeIAdIgge sapoo ANUNOT ‘odomng wz uaTye sordods oyu DY JO soMsTIDIOeIeYO pur IST] *T pz ZIGeL

(S661) wnIeNS UeA pure UaINoP{
ueA ‘(€66]) WNIeING ULA pur UaINoPy

Maria Navajas et al./ BioRisk 4(1): 149-192 (2010)

192

uvA “(FQ0Z) ‘Te 19 POUESUAg “(G00Z) (6881 2se]I0q)
eYANISe'] Pur PAOTJIS ‘(ZYOTZ) Odd | S#grhunuzay, TLed'E joyepoid supsauadsap
“(Z661) HOPIe ‘(666T1) ‘Je 29 sofeqry | jo Joxeposg I WD ‘FD ‘Z| ZO ‘E661 | ueouessoupeypy /orisered (snisagdy) sniasquy
seprosovdyg
IS (2681 JM>qNL)\
(6007) voedoing euney XIADT WH ‘9D Ad‘vga snoseydoikyg SIITAD] SNIVIASIAT.
sepndordyg
(9861) Id ‘ON

‘ye Jo PURUTOTIS “(Q8G[) ‘Je 39 UaqIery “IN “Al ‘GD Na uOoIsaI joyepoid (9081 2[foe7T)
‘(6007) vaedoing euney “(¢g61) AUIE_D ssoq {| ad ‘ZO ‘HD “Ag | UMouyuY | URsUeIIOIpopy jouusered | snauinsuvs snyvgdasidigy

odoin ut satoadg

SOIUIIIFOY s}sOP] ,Jeuqey | serunos papeayy | proses ys] | oSues aaryeNy Ayrure,y