Download Key Role of European Rabbits in the Conservation of the Western

Key Role of European Rabbits in the Conservation
of the Western Mediterranean Basin Hotspot
MIGUEL DELIBES-MATEOS,∗ †§ MIGUEL DELIBES,‡ PABLO FERRERAS,∗
AND RAFAEL VILLAFUERTE∗
∗
Instituto de Investigación en Recursos Cinegéticos, IREC (CSIC-UCLM-JCCM), Ronda de Toledo s/n, 13071-Ciudad Real, Spain
†Departamento de Biologı́a Animal, Facultad de Ciencias, Universidad de Málaga, 29071-Málaga, Spain
‡CSIC, Department of Applied Biology, Estac Biol Donana, ES-41013 Seville, Spain
Abstract: The Mediterranean Basin is a global hotspot of biodiversity. Hotspots are said to be experiencing a
major loss of habitat, but an added risk could be the decline of some species having a special role in ecological
relationships of the system. We reviewed the role of European rabbits (Oryctolagus cuniculus) as a keystone
species in the Iberian Peninsula portion of the Mediterranean hotspot. Rabbits conspicuously alter plant
species composition and vegetation structure through grazing and seed dispersal, which creates open areas
and preserves plant species diversity. Moreover, rabbit latrines have a demonstrable effect on soil fertility and
plant growth and provide new feeding resources for many invertebrate species. Rabbit burrows provide nest
sites and shelter for vertebrates and invertebrates. In addition, rabbits serve as prey for a number of predators,
including the critically endangered Iberian lynx (Lynx pardinus) and Spanish Imperial Eagle (Aquila adalberti).
Thus, the Mediterranean ecosystem of the Iberian Peninsula should be termed “the rabbit’s ecosystem.” To our
knowledge, this is the first empirical support for existence of a multifunctional keystone species in a global
hotspot of biodiversity. Rabbit populations have declined drastically on the Iberian Peninsula, with potential
cascading effects and serious ecological and economic consequences. From this perspective, rabbit recovery is
one of the biggest challenges for conservation of the Mediterranean Basin hotspot.
Keywords: biodiversity hotspot, ecosystem engineer, European rabbit, hotspot conservation, keystone species,
Mediterranean ecosystem, Oryctolagus cuniculus
Papel Clave de Conejos Europeos en la Conservación del Área de Importancia del Mediterráneo Occidental
Resumen: La Cuenca del Mediterráneo es un área de importancia para la biodiversidad global. estas áreas
de importancia están experimentando una gran pérdida de hábitat, pero el declive de algunas especies que
juegan un papel especial en las relaciones ecológicas del sistema pudiera ser un riesgo adicional. Revisamos
el papel del conejo europeo (Oryctolagus cuniculus) como especie clave en la porción del área de importancia
Mediterráneo en la Penı́nsula Ibérica. Los conejos conspicuamente alteran la composición de especies de
plantas y la estructura de la vegetación por medio del pastoreo y la dispersión de semillas, lo cual crea
áreas abiertas y preserva la diversidad especies de plantas. Más aun, las letrinas de conejos tienen un
efecto demostrable sobre la fertilidad del suelo y el crecimiento de plantas y proporcionan nuevos recursos
alimenticios para muchas especies de invertebrados. Las madrigueras de los conejos proporcionan espacio
para la nidificación y refugio a vertebrados e invertebrados. También, los conejos sirven como presa para un
nú mero de depredadores, incluyendo al lince ibérico (Lynx pardinus) en peligro crı́tico y al águila imperial
(Aquila adalberti). Por lo tanto, el ecosistema Mediterráneo de la Penı́nsula Ibérica deberı́a ser denominado el
“ecosistema de los conejos.” Hasta donde sabemos, este es la primera evidencia empı́rica de la existencia de
una especie clave multifuncional en un área de importancia para la biodiversidad global. Las poblaciones
§Address for correspondence: Departamento de Biologı́a Animal, Facultad de Ciencias, Universidad de Málaga, 29071- Málaga, Spain,
email [email protected]
de conejos han declinado drásticamente en la Penı́nsula Ibérica, con potenciales efectos en cascada y serias
consecuencias ecológicas y económicas. Desde esta perspectiva, la recuperación de conejos es uno de los
mayores retos para la conservación del área de importancia de la Cuenca del Mediterráneo.
Palabras Clave: área de importancia para la biodiversidad, conservación de área de importancia, ecosistema
del Mediterráneo, especies clave, ingeniero de ecosistemas, Oryctolagus cuniculus
Introduction
As many as 34 global biodiversity hotspots, described as
“areas featuring exceptional concentrations of endemic
species and experiencing exceptional loss of habitat,”
have been identified (Myers et al. 2000; Mittermeier et al.
2005). A usually overlooked risk for hotspots is the decline or disappearance of some key species, which could
produce catastrophic cascading effects on the whole system (Chapin et al. 2000). We reviewed the key role of
European rabbits (Oryctolagus cuniculus) at the western corner of the Mediterranean Basin hotspot. Rabbit
populations are currently declining in this area (Ward
2005), which should be a cause for concern in conservation of the composition, functions, and processes of this
hotspot.
Mediterranean-type ecosystems occur in rather small
areas in America (California and Chile), South Africa,
Australia, and around the Mediterranean Sea (Di Castri
& Mooney 1973). These areas, characterized by hot, dry
summers and mild, rainy winters, are centers of biodiversity, second only to the tropics in importance (Cowling
et al. 1996). The Mediterranean Basin hotspot includes
the Iberian Peninsula, which was a refuge for temperate
species during past glaciations (Taberlet et al. 1998). Its
high mountains (e.g., Sierra Nevada, southern Spain, approximately 3500 m asl) are a southern refuge for northern ecotypes. Consequently, a large number of endemic
species occur in Mediterranean Iberia (e.g., over 1500
endemic species in the Spanish flora; MMA 2008).
Iberian Mediterranean natural habitats have been lost
to, for example, cultivation, tree plantations, reservoirs,
and urbanization (e.g., Symeonakis et al. 2007). Nevertheless, an additional risk could be the decline of the
European rabbit, which is endemic to the Iberian Peninsula (Monnerot et al. 1994). From the late Pleistocene
until Classical antiquity, European rabbits were present
only on the Iberian Peninsula and in a small area in southern France (Monnerot et al. 1994). The species is now
distributed widely in Europe, South America, Australia,
and many oceanic islands (Gibb 1990) as a consequence
of human introductions.
European rabbits are opportunistic and highly adaptable, which explains their success as colonists (Gibb
1990). Because of their wide distribution and their potentially high population densities, rabbits have pronounced
effects on biological diversity and ecosystem functions.
Where introduced, they can destroy vegetation, damage farm crops, compete with livestock and native wild
species, and cause severe ecological damage (Thompson
& King 1994). Consequently, numerous attempts have
been made to eradicate introduced rabbits, including the
artificial spread of exotic disease agents (Angulo & Cooke
2002).
In spite of recent population declines (see later), rabbits still can reach high abundances in some of their
natural Mediterranean habitats, where their ecological
effects are evident (Ward 2005). Nevertheless, because
they evolved in this area, they are central to processes
that maintain integrity of biodiversity in the region. We
reviewed the role of rabbits as ecosystem engineers, with
specific focus on their effects on vegetation structure and
composition, through herbivory and seed dispersal; the
importance of their latrines for soil condition and for
invertebrates; and their effects as diggers, providing a
refuge for a variety of animal species. We also considered
the role of rabbits as prey for many Iberian predators. We
discuss current trends in rabbit abundance and the potential implications of these trends for the conservation
of biodiversity in the western corner of Mediterranean
Basin hotspot.
Because most of the studies we reviewed were conducted in recent decades, after the rabbit decline began
on the Iberian Peninsula, we focused primarily on qualitative rather than quantitative aspects of their role in the
ecosystem. Nevertheless, it is likely that their effects on
the ecosystem were greater before their decline than they
are now. Because there is little scientific information on
rabbit populations in this area beyond 30 years ago, we
occasionally drew on information from other regions.
The Rabbit as an Ecosystem Engineer
Abiotic environmental conditions and species interactions have been proposed as determinants of species diversity patterns in natural communities (Tilman 1999).
Even though all species interact with their physical environment, some organisms substantially influence environmental conditions and resource availability and thus
affect other species and the community attributes of natural species assemblages. Jones et al. (1994) coined the
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Volume 22, No. 5, 2008
Figure 1. Dominant pathways
by which European rabbits
affect ecosystem structure and
function in the Mediterranean
area of the Iberian Peninsula
(inspired by Kotliar et al. 1999).
phrase physical ecosystem engineering for this biotic
process and physical ecosystem engineers to refer to the
organisms responsible for such habitat changes.
Rabbits are special among leporids because they form
colonies, reach high densities, and dig warrens (Gibb
1990). The primary rabbit activities that have ecosystemlevel consequences are herbivory, seed dispersal, digging
(warren building and scratching), and depositing feces,
mainly at latrines (Fig. 1).
Rabbit Grazing and Plant Species Diversity
Many researchers have noted the effects of rabbit grazing
on the composition and structure of plant communities
(e.g., Watt 1981; Eldridge & Simpson 2002). Although
most of these studies concern areas where rabbits are
considered a pest, a number have been made in the
Iberian ecosystem. Soriguer (1981) estimated that rabbits
consume approximately 15% of the available vegetation
biomass in Doñana National Park, southwestern Spain. In
a recent study in central Spain, Rueda (2006) observed
that rabbits eat 42% of the total aboveground biomass,
equivalent to 80% of the biomass consumed by all vertebrate herbivores in this area. Where rabbits are numerous
(>40 individuals/ha have been recorded in some areas, in
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Volume 22, No. 5, 2008
spite of diseases; Palomares 2001), they have substantial
effects on the aboveground flow of energy and materials. Consequently, excluding rabbit grazing from a plant
community causes marked changes in community composition (Garcı́a-Fuentes et al. 2006; Rueda 2006).
Rabbits exhibit high grazing selectivity in areas where
they have been introduced (Leigh et al. 1989); hence,
palatable or preferred plants are less abundant where
rabbits reach high numbers (Eldridge & Simpson 2002).
In southern Spain, the abundance of palatable plants
(mainly Poaceae and Fabaceae species) decreases in
rabbit-grazed grasslands, whereas that of less-preferred
species (mainly Asteraceae species) increases (Garcı́aFuentes et al. 2006). Some plant species may increase
in abundance where rabbits are grazing because of reduced interspecific competition (Crawley 1990). In addition, continuous rabbit grazing reduces mean plant size
and increases size inequality (Crawley & Weiner 1991),
although the largest plants can occur in grazed areas due
to reduction in competition (Eldridge & Simpson 2002).
Herbivory by rabbits influences spatial patterns of
dominant woody species in the Mediterranean landscape. Gómez-Sal et al. (1999) demonstrated that disturbance by rabbits produces Retama sphaerocarpa
patches with fewer, more scattered, thicker-branched,
and larger shrubs (i.e., an open scrubland or savannahtype structure). Thus, rabbits promote the maintenance
of open scrubland, which is their preferred habitat
(Moreno & Villafuerte 1995). In contrast, anthropogenic
disturbances, such as mechanical cutting or fires, tend
to produce denser shrubs with a greater canopy biomass
(Gómez-Sal et al. 1999), which is unsuitable as rabbit
habitat.
The activity of rabbits in creating mosaics of open
areas and promoting growth of an herbaceous layer in
scrubland (Gómez-Sal et al. 1999; see also Oosterveld
1983) may facilitate settlement of other herbivores that
depend on this type of habitat. Grazing by rabbits and
brown hares (Lepus europaeus) in some regions of the
Netherlands prevents tall plant species from becoming
dominant, which enhances feeding conditions for Brent
Geese (Branta bernicla) (van der Wal et al. 2000). On
the Iberian Peninsula, where the small mammal community is richer than in other Mediterranean areas (Cagnin
et al. 1998), rabbit grazing may favor several species of
small mammals because their preferred habitat, ecotones
between cover and open areas (e.g., Hansson 1998), is
promoted by rabbit grazing. Moreover, the predation risk
for small mammals may be higher in open areas, such as
those created by rabbits. Thus, predators associated with
open areas would benefit indirectly from rabbit grazing.
Therefore, rabbits tend to increase habitat complexity
and heterogeneity, causing species abundances and/or
richness to rise.
Endozoochorous Seed Dispersal by Rabbits
In recent decades a considerable body of knowledge has
accumulated regarding the role of frugivores as seed dispersers in the Mediterranean region (Jordano & Schubb
2000). Rabbits damage some kinds of seeds in their gastrointestinal tract (J. M. Fedriani, personal communication), but their dung can contain viable seeds from a
large range of herbaceous, shrub, and tree species. In
the Mediterranean region, these include at least 72 plant
species belonging to 23 different families (Table 1). In
some instances, seed germination rate and success are
higher in seeds in rabbit dung (Cerván Carmona & Pardo
Navarro 1997; Dellafiore et al. 2006).
Typically a small proportion of rabbit pellets contain
seeds (approximately 2.5%; Malo et al. 2000; Dellafiore
et al. 2006). Nevertheless, the number of seeds dispersed
by rabbits during the year is large because there are
usually several individuals per hectare and each individual produces approximately 325 pellets per day (Wood
1988). Rabbits are thus very important seed vectors, contributing to plant population recruitment and facilitating
long-distance dispersal of seeds into habitats not previously colonized (Dellafiore et al. 2006).
Rabbits eat the fruiting bodies of fungi (Alves et al.
2006), and they likely disperse fungal spores that de-
velop mycorrhizal associations, contributing to the development of vegetation, as occurs in other small mammals
(Dickman 1999; Johnson 1996). To our knowledge this
important topic has not been addressed.
Rabbit Latrines, Soil Nutrients, and Dung Beetle Diversity
As well as scattering fecal pellets, rabbits deposit a large
number of pellets (sometimes >1000) that serve a social
function in latrines. Latrines can be used for a number of
years (Gibb 1993). Although the use of latrines varies
among rabbit populations, latrine use is usually high
when rabbits are abundant. Densities of almost 80 and
110 latrines/ha have been reported from central Spain
(Gálvez et al. 2008) and southern Spain (Petterson 2001),
respectively.
Dung deposition by stock animals creates localized
patches of high nutrient concentrations that affect the
sward and soil microbial activity (Lovell & Jarvis 1996).
Rabbit fecal pellets have total N and P concentrations
comparable to the dung of stock animals; hence, latrines
have a demonstrable effect on soil fertility and plant
growth, creating fertile islands between shrubs (Willot
et al. 2000). In southern Spain rabbit latrines alter composition, density, and biomass of the surrounding vegetation (e.g., a 3-fold increase of biomass and 16% less
bare ground; Petterson 2001). Therefore, by importing
nutrients to latrines, rabbits create heterogeneity and increase diversity in the semiarid Mediterranean ecosystem
(Petterson 2001).
Rabbit latrines also provide new feeding resources for
many invertebrate species. For instance, Mediterranean
dung beetles, including Onthophagus latigena and O.
emarginatus, are frequently collected from rabbit pellets (Sánchez-Piñero & Ávila 1991; Galante & Cartagena
1999). The availability and abundance of dry pellets (especially from rabbits) seem to be key factors in the evolutionary diversification and high level of endemism in
Mediterranean dung beetles (Verdú & Galante 2002).
Some species associated with rabbit pellets show anatomical adaptations of their mouth parts (e.g., prominent denticles and well-developed molar areas) that apparently favor exploitation of dry fibrous dung, such as rabbit pellets
(Verdú & Galante 2004).
Rabbit Warrens and Surface Digging
As their scientific name implies (oryktes means digger
in Greek), rabbits are burrowing animals that live communally in warrens (Gibb 1990). The importance of warrens to rabbits has been highlighted by many authors
(Kolb 1991; Palomares 2003), and large, healthy rabbit
populations are usually associated with high warren densities (Blanco & Villafuerte 1993). Warren densities vary
greatly. The highest density reported to date was 496
burrow entrances/ha in Britain (Kolb 1991). In southwestern Spain, Palomares (2001) estimated a total of
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Volume 22, No. 5, 2008
Table 1. Plant species reported to be dispersed by European rabbits in the Iberian Peninsula.
Plant species
Andryala integrifolia
Apera interrupta
Aphanes microcarpa
Arabidopsis thaliana
Arenaria leptoclados
Armeria gaditana
Asparagus aphyllus
Asphodelus aestivus
Biserrula pelecinus
Brassica barrelieri
Campanula erinus
Capsella bursa-pastoris
Cerastium glomeratum
C. semidecandrum
Cistus ladanifer
Cis. salvifolius
Crassula tillaea
Corema album
Crepis capillaris
Cruciata pedemontana
Erophila verna
Filago pyramidata
Galium murale
G. parisiense
G. spurium
Halimium halimifolium
Heliotropium europaeum
Herniaria hirsuta
Juncus bufonius
J. inflexus
Juniperus macrocarpa
Jun. phoenicea
Lavandula stoechas
Legousia castellana
Logfia minima
Lophocloa cristata
Myosotis persoonii
Myo. stricta
Olea europaea
Parentucellia latifolia
Phillyrea angustifolia
Pistacia lentiscus
P. terebinthus
Plantago afra
Pla. coronopus
Pla. loeflingii
Poa annua
Po. bulbosa
Polycarpon tetraphyllum
Polypogon monspeliensis
Retama monosperma
R. sphaerocarpa
Rosmarinus officinalis
Sagina apelata
Sisymbrium runcicatum
Spergularia purpurea
Stellaria media
Trifolium campestre
T. cernuum
T. glomeratum
T. retusum
T. suffocatum
Family
References
Asteraceae
Poaceae
Rosaceae
Brassicaceae
Caryophyllaceae
Plumbaginaceae
Liliaceae
Liliaceae
Leguminosae
Brassicaceae
Campanulaceae
Brassicaceae
Caryophyllaceae
Caryophyllaceae
Cistaceae
Cistaceae
Crassulaceae
Empetraceae
Asteraceae
Rubiaceae
Brassciaceae
Asteraceae
Rubiaceae
Rubiaceae
Rubiaceae
Cistaceae
Boraginaceae
Caryophyllaceae
Juncaceae
Juncaceae
Cupressaceae
Cupressaceae
Lamieaceae
Campanulaceae
Asteraceae
Poaceae
Boraginaceae
Boraginaceae
Oleaceae
Scrophulariaceae
Oleaceae
Anacardiaceae
Anacardiaceae
Plantaginaceae
Plantaginaceae
Plantaginaceae
Poaceae
Poaceae
Caryophyllaceae
Poaceae
Leguminosae
Leguminosae
Lamieaceae
Caryophyllaceae
Brassicaceae
Caryophyllaceae
Caryophyllaceae
Leguminosae
Leguminosae
Leguminosae
Leguminosae
Leguminosae
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Rogers et al. 1994
Rogers et al. 1994
Rogers et al. 1994
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Rogers et al. 1994
Malo & Suárez 1995; Malo et al. 1995
Soriguer 1986; Rogers et al. 1994
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Rogers et al. 1994
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Rogers et al. 1994; Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Soriguer 1986
Muñoz Reinoso 1993; Rogers et al. 1994
Rogers et al. 1994
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Soriguer 1986; Rogers et al. 1994
Malo & Suárez 1995; Malo et al. 1995
Rogers et al. 1994
Rogers et al. 1994
Rogers et al. 1994
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Dellafiore et al. 2006
Rogers et al. 1994; Cerván Carmona & Pardo Navarro 1997
Rogers et al. 1994
Malo & Suárez 1995; Malo et al. 1995; 2000
Malo & Suárez 1995; Malo et al. 1995; 2000
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
Malo et al. 1995
Malo & Suárez 1995; Malo et al. 1995
continued
Conservation Biology
Volume 22, No. 5, 2008
Table 1. (continued)
Plant species
T. tomentosum
Tuberaria guttata
Urtica urens
Veronica arvensis
V. verna
Viola kitaibeliana
Vulpia bromoides
Vul. ciliata
Vul. muralis
Vul. unilateralis
Family
Leguminosae
Cistaceae
Urticaceae
Scrophulariaceae
Scrophulariaceae
Violaceae
Poaceae
Poaceae
Poaceae
Poaceae
266 warren entrances/ha (7 warrens/ha) and an average of 38.1 entrances/warren in areas of Mediterranean
scrubland within Doñana National Park. Thus, rabbit warrens are important components of the Mediterranean
landscape. Garcı́a y Bellido (1945) quoted classic Greek
and Roman authors who recorded that the burrowing activity of rabbits in ancient times was sufficient to undermine the buildings of entire cities in the Baleares Islands.
Rabbit warrens provide new feeding and refuge areas
for many other species (Gálvez et al. 2008). For instance,
rabbits in Spain support at least 22 genera of ectoparasites (compared with 8 in Australia, 7 of which also
have been recorded in Spain; Soriguer 1980). Among
these are several species of rabbit flea (Spilopsyllus cuniculi, Xenopsylla cunicularis, Echidnophaga iberica,
Caenopsylla laptevi, Odontopsyllus quirosi) that can be
found in high numbers in rabbit warrens (Rogers et al.
1994) and can act as important disease vectors for rabbits
and other species (Osácar-Jiménez et al. 2001).
Amphibians, reptiles, mammals, and some birds frequently use rabbit warrens. The common toad (Bufo
bufo), the natterjack toad (B. calamita), the common
midwife toad (Alytes obstetricans), and the newt (Pleurodeles waltl) occur in rabbit warrens (authors’ unpublished data). Blázquez and Villafuerte (1990) observed
the Montpellier snake (Malpolon monspessulanus) nesting inside rabbit warrens, and other snakes and some
lizard species (Gálvez 2008) also inhabit rabbit warrens.
Among small mammals, the garden dormouse (Eliomys
quercinus), wood mouse (Apodemus sylvaticus), Algerian mouse (Mus spretus), and 2 species of rat (Rattus
norvegicus, R. rattus) have been found inside rabbit
warrens (authors’ unpublished data). Several species of
carnivores use rabbit burrows as refuges. For instance,
Eurasian badgers (Meles meles) commonly construct diurnal resting dens by enlarging existing rabbit warrens
(Revilla et al. 2001). Other carnivores, such as the polecat (Mustela putorius), Egyptian mongoose (Herpestes
ichneumon), red fox (Vulpes vulpes), and weasel (M. nivalis), also use rabbit warrens as resting sites (Blas-Aritio
1970; Palomares & Delibes 1993; C. Rouco, personal
communication). Female Iberian lynx (Lynx pardinus)
References
Malo &
Malo &
Malo &
Malo &
Malo &
Malo &
Malo &
Malo &
Malo &
Malo &
Suárez 1995; Malo et al. 1995
Suárez 1995; Malo et al. 1995
Suárez 1995; Malo et al. 1995
Suárez 1995; Malo et al. 1995
Suárez 1995; Malo et al. 1995
Suárez 1995; Malo et al. 1995
Suárez 1995; Malo et al. 1995
Suárez 1995; Malo et al. 1995
Suárez 1995; Malo et al. 1995
Suárez 1995; Malo et al. 1995
and wolves (Canis lupus) use enlarged rabbit warrens
as temporary shelter for their young (authors’ unpublished data). Some birds, such as the Little Owl (Athene
noctua), use rabbit warrens as nesting places (authors’
unpublished data).
Like other species of small mammals (Dickman 1999),
rabbits may also affect nutrient cycling, water flow, soil
structure, and microtopography with their continuous
and intensive digging (warren building and scratching).
Rabbits as Prey for Humans and Other Animals
Small mammals such as rabbits were a major component
of the diet of Iberian people from the Palaeolithic to the
Bronze Age (e.g., Callou 2003). The use of wild rabbits
decreased after the species was domesticated, but wild
rabbit meat was valuable even during the first decades of
the 20th century (Delibes 1972). Today, rabbit hunting
is an economically important sport on the Iberian Peninsula. In Spain over 30,000 private hunting estates cover
over 70% of the country (Angulo & Villafuerte 2003),
more than 1 million people hunt every year, and many
of these people preferentially hunt rabbits (Rogers et al.
1994). Despite the recent history of dramatic decreases
or even localized extinction of many rabbit populations
(Villafuerte et al. 1995), rabbits are still the most-hunted
species in Spain in both number and biomass (>4 million rabbits are currently harvested annually; INE 2006;
Fig. 2).
Rabbits are also an important prey species for many
wild predators in the Iberian Mediterranean ecosystem
(Table 2; see also Valverde 1967; Ward 2005). In Spain,
for example, rabbits are important prey for more than 30
nocturnal and diurnal predators (Delibes & Hiraldo 1981).
Large predators tend to consume more rabbits and, with
the exception of the wolf, all predators of medium and
large size (>3 kg among the mammals and >1.5 kg among
the birds) feed primarily on rabbits when they occur at
high density, whereas nearly all smaller predators use
rabbits as alternative prey (Delibes & Hiraldo 1981; Jaksic
& Delibes 1987).
Conservation Biology
Volume 22, No. 5, 2008
Oryctolagus cuniculus
Alectoris rufa Lepus
spp
Sus scrofa
Cervus elaphus
0
1
2
3
4
5
Individuals hunted (millions)
Figure 2. Number of individuals of the primary game species taken by hunters in Spain during the 2001 hunting
season (INE 2006).
Two flagship species of conservation concern in Europe, the Spanish Imperial Eagle (Aquila adalberti) and
the Iberian lynx, both endemic to the Iberian Mediterranean ecosystem, probably evolved as “super specialists” on rabbits. Rabbits constitute over 85% of the diet
of the Iberian lynx (Table 2). Moreover, rabbit densities
of at least 1–4.6 rabbits/ha (during autumn and spring,
respectively) are necessary to sustain territorial breeding
lynx (Palomares et al. 2001). The proportion of rabbits in
the diet of Spanish Imperial Eagles is rather low (Table 2),
but a recent study demonstrated that eagle distribution
is strongly correlated with areas of high rabbit density
(Delibes-Mateos et al. 2007). That Spanish Imperial Eagle
and the Iberian lynx preyed on rabbits in the Pleistocene
refugium of southern Spain may have played an essential role in the phylogenetic segregation of these species
from their sister species, the Eastern Imperial Eagle (A. heliaca) and the Eurasian lynx (L. lynx), respectively (Ferrer
& Negro 2004).
Several Mediterranean species are facultative rabbit
predators, specializing locally on rabbits where they are
abundant. At high densities rabbits are ideal prey because
of their high energetic value and low catchability costs
(Revilla & Palomares 2002; Malo et al. 2004). Facultative
predators include carnivores and birds of prey, some of
them of international conservation concern, such as the
Bonelli’s Eagle (Hieraaetus fasciatus; Table 2).
Many other predator species feed opportunistically on
rabbits. For instance, the high availability of young and
juvenile rabbits in spring provides an important food resource for several small birds of prey and generalist carnivores. Viñuela and Veiga (1992) observed a positive relationship between the breeding success of the Black Kite
(Milvus migrans) and the proportion of its diet consisting of juveniles or sick rabbits. Some scavengers of international conservation concern, such as the Black Vulture
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Volume 22, No. 5, 2008
(Aegypius monachus) (Hiraldo 1976), consume rabbit
carcasses and kill juvenile rabbits in areas where rabbit
density is high. The rare Bearded Vulture (Gypaetus barbatus) consumes rabbits in the Pyrenees (Margalida et al.
2005). Rabbits were probably an important resource for
this species before it disappeared from southern Spain
(Hiraldo et al. 1979). Other species feed occasionally on
rabbits, but they represent a small proportion of their diet
even when rabbit densities are high (Table 2). According
to Valverde (1967), big Montpellier snakes became scarce
in Doñana National Park after introduction of myxomatosis in the 1950s and subsequent decline of rabbits (the
snakes’ main prey).
The only estimate of the absolute number of rabbits
consumed by the entire predator community in Mediterranean Spain was made by Kufner (1986) for Doñana
Biological Reserve, southwestern Spain, before arrival of
the rabbit hemorrhagic disease (RHD). She suggests that
predators consumed about 51,000 rabbits annually in the
6,000-ha reserve, equivalent to more than 8 rabbits/ha.
Rabbits constitute an important food source for many
predators in the Mediterranean ecosystem. It is not surprising that the abundance of raptor species (species that
take rabbits or scavenge on rabbit carcasses) is highly correlated with rabbit abundance in southern Spain (DelibesMateos et al. 2007). Consequently, rabbit abundance may
allow pinpointing areas of current or future concern for
conservation of predator species that are rare at the global
or European scale.
Rabbit Decline and Its Implications for
Conservation
Mediterranean-type ecosystems are good models for
studying the impacts of global change and the
1113
Delibes-Mateos et al.
Table 2. Contribution of rabbits to the diet of the main Iberian predators.a
Main
rabbit
predators
Carnivores
Canis lupus
Felis silvestris
Genetta genetta
Herpestes ichneumon
Lynx pardinus
Martes foina
Meles meles
Mustela putorius
Vulpes vulpes
Birds of prey
Accipiter gentilis
Aegypius monachus
Aquila chrysaetos
A. adalberti
Bubo bubo
Buteo buteo
Circus aeruginosus
Cir. cyaneus
Cir. pygargus
Hieraaetus fasciatus
H. pennatus
Milvus migrans
Mil. milvus
Neophron percnopterus
Strix aluco
Other predators
birds: Accipiter nisus, Athene noctua, Ciconia ciconia,
Circaetus gallicus, Corvus corax, Elanus caeruleus,
Falco columbarius, F. peregrinus, F. subbuteo, F.
tinnunculus, Grus grus, Gypaetus barbatus, Gyps
fulvus, Larus argentatus, Tyto alba; mammals:
Erinaceus algirus, E. europaeus, Mustela nivalis, Sus
scrofa; reptiles: Elaphe scalaris, Lacerta lepida,
Malpolon monpessulanus
Type of
rabbit
predator
Rabbit in
diet (%)
(min-max)b
IUCN
statusc
opportunist
facultative
opportunist
facultative
specialist
opportunist
facultative
opportunist
facultative
0–44.4
0–64
2.8–11.4
22.2–80.3
77.5–99.5
0–20.4
0.01–61.8
0–30
0–96.1
NT
VU
LC
DD
CE
LC
LC
NT
LC
opportunist
facultative
facultative
specialist
facultative
opportunist
opportunist
opportunist
opportunist
facultative
opportunist
opportunist
opportunist
opportunist
opportunist
12–22.4
23.9–70.7
13–63.2
27.4–55.8
16.9–67.5
0–66.6
0–22.8
0–31.9
1–17.2
12.6–51
2–60
1.6–56.7
8.3–29.2
2.5–49.3
8–38.27
LC
VU
NT
EN
LC
LC
LC
LC
VU
EN
LC
NT
EN
EN
LC
occasional
0–<5
—
a Data
from Delibes and Hiraldo (1981), Valkama et al. (2005), and Moleón (2007).
of occurrence (gut contents or scats) for carnivores and percentage of total prey remains for birds of prey.
c Category definitions: CE, critically endangered; DD, data deficient; EN, endangered; LC, least concern; NT, near threatened; VU, vulnerable.
b Percentage
relationship between biological diversity and ecological
function (Lavorel et al. 1998). Introduced species, including microorganisms, are an important component of
human-induced change (Vitousek et al. 1997). Species introductions risk modifying the functioning of the Iberian
Mediterranean ecosystem through their effects on rabbit
populations because 2 exotic viral diseases, myxomatosis in the 1950s and RHD at the end of the 1980s, are
the main causes of a sharp decline in rabbits in recent
decades (Muñoz 1960; Villafuerte et al. 1995). Both diseases were introduced as biological control agents in areas where rabbits are considered a pest (Angulo & Cooke
2002). The rabbit population in Spain declined by an estimated 70% between 1973 and 1993 (Virgós et al. 2007).
An even greater decline, perhaps over 90%, may have
occurred because of myxomatosis in the 1950s; this disease has killed 90–100% of all rabbits in other regions
(e.g., Armour & Thompson 1955). The decline of rabbits
in the Iberian Peninsula has been almost general, but recovery has been spatially uneven. In many areas rabbits
are extinct or survive at low densities, but in other areas their numbers are high enough to allow hunting. The
recovery seems to have been greater in hunting areas
(Delibes-Mateos et al. 2008a); hence, rabbit densities are
currently lower in protected areas, perhaps because of
different management practices and predation pressures
(Delibes-Mateos 2006). Nevertheless, local and regional
declines have been so acute in some parts of the Iberian
Peninsula that rabbits have been recently classified as
near threatened by the Portuguese Institute for Nature
Conservation (Cabral et al. 2005) and as vulnerable on
the Spanish Red List (Villafuerte & Delibes-Mateos 2007).
Ecosystem processes can exhibit abrupt thresholds owing to the severe decline of a key species (Chapin et al.
2000). The decline in rabbit numbers could have important cascading effects on functioning of the Iberian
Conservation Biology
Volume 22, No. 5, 2008
1114
Mediterranean ecosystem and serious ecological and economic consequences. Some of these effects are becoming evident. For instance, considerable effort and funds
are being expended to reestablish rabbit populations for
sport hunting and to provide resources for predators
through measures such as vaccination against diseases
and restocking programs (Calvete et al. 1997; Moreno
et al. 2004). Although 2 genetic lineages of rabbits are
recognized, restocking practices frequently ignore this,
risking conservation of genetic diversity (Delibes-Mateos
et al. 2008b). Management actions are often not successful because the decline of rabbit numbers makes an area
less suitable for subsequent recolonization (rabbits engineer the habitat to their own benefit by, for instance,
opening it up and promoting the growth of an herbaceous layer). Opening the scrubland may have important
indirect effects, such as reducing the amount of available combustible material and thus reducing the risk of
catastrophic field fires (e.g., Piñol et al. 1998).
It is widely accepted that the dramatic decrease in
rabbit numbers has affected the reproductive success of
some predators (Fernández 1993; Real & Mañosa 1997).
Moreover, declines in the Iberian lynx and the Spanish
Imperial Eagle seem to be at least partially due to reductions in rabbit abundance (Moreno et al. 2004). The
rabbit decline must be affecting many other aspects of
the Iberian Mediterranean ecosystem, including availability of refuges (for invertebrates, lizards, amphibians, and
mammals), nutrient cycling, diversity of plant species,
and abundance of specialist rabbit-pellet dung beetles.
Evidence of the consequences for other communities and
ecological processes caused by rabbit decline is currently
lacking because there have been no long-term studies in
the Mediterranean ecosystem. Nevertheless, a wide variety of studies conducted in other areas indicate that
rabbit decline does affect other communities (e.g., plant
and invertebrate communities) and ecological processes
(Priddel et al. 2000 and references therein). Perhaps many
Mediterranean species and processes have already been
affected by the recent decline in rabbit abundance on the
Iberian Peninsula.
Conclusions: the Rabbit’s Ecosystem
According to Power et al. (1996), a keystone species
should have disproportionately large effects relative to its
abundance, which seems to exclude abundant species,
such as the European rabbit. Nevertheless, Kotliar (2000)
proposed that species performing roles not performed
by other species and processes should also be considered
keystone species regardless of their abundance. Undoubtedly, rabbits fit this definition because they are crucial for
maintaining the organization, functioning, and diversity
of the ecological community. Mills et al. (1993) classified 5 functional types of keystone species: predators,
Conservation Biology
Volume 22, No. 5, 2008
Rabbits and the Mediterranean Basin
prey, hosts, mutualists, and habitat modifiers. Rabbits fulfill almost all these functions in the Iberian Mediterranean
ecosystem (Fig. 1). The role of rabbits as an important
prey species in Mediterranean Iberia has been debated
previously, but this is the first review of the different key
roles that rabbits play in this global biodiversity hotspot.
Rabbits are so important in the Mediterranean scrubland
of southwestern Europe that this ecosystem could be
considered “the rabbit’s ecosystem.”
The contribution of other small mammals to ecosystem
diversity and function has been shown previously (e.g.,
many rodents; Dickman 1999). Some species of small
mammals are also keystone species because of their abundance and ecological importance. The role of rabbits in
the Mediterranean ecosystem closely resembles that of
the plateau pika (Ochotona curzoniae), a keystone lagomorph of the Tibetan plateau (Smith & Foggin 1999). The
pika makes burrows that are the primary home to a variety
of species, creates microhabitat disturbance, serves as the
principal prey for several predators, and contributes positively to ecosystem-level dynamics. The role of rabbits in
southern Europe is akin to the functional role of prairie
dogs (Cynomys spp.) in prairie ecosystems of the United
States because both are social-burrower species and can
occur at high densities (Kotliar et al. 1999; Kotliar 2000).
To our knowledge we present the first empirical evidence for the existence of a multifunctional keystone
species in 1 of the 34 identified biodiversity hotspots.
By definition, keystone species have a disproportionately
large influence and their elimination or a large decline
in numbers typically has a major effect on populations
of other species and ecosystem processes (Chapin et al.
2000). Mediterranean scrubland biota in Spain has
changed significantly in the last 30 years. Although it is
difficult to say how much of this change is due to the decline of rabbits, it is likely that rabbit recovery will be one
of the greatest challenges for the long-term conservation
of this biodiversity hotspot (Ward 2005).
Acknowledgments
M.D.M. was supported by a postdoctoral grant funded by
the regional government of Castilla la Mancha (JCCM).
Funding was provided by the projects FAU2006-00014C02-02, PAI 06-0170, and CGL 2005-02340/BOS. Special
thanks go to people who provided valuable information
for this review. We thank E. Main, G. Meffe, K. Paige, J.
Swenson, and 2 anonymous reviewers for their helpful
comments on previous drafts of the Manuscript.
Literature Cited
Alves, J., J. Vingada, and P. Rodrigues. 2006. The wild rabbit (Oryctolagus cuniculus) diet on a sand dune area in central Portugal:
a contribution towards management. Wildlife Biology in Practice
2:63–71.
1115
Delibes-Mateos et al.
Angulo, E., and B. Cooke. 2002. First synthesize new viruses then regulate their release? The case of the wild rabbit. Molecular Ecology
11:2703–2709.
Angulo, E., and R. Villafuerte. 2003. Modelling hunting strategies for
the conservation of wild rabbit populations. Biological Conservation
115:291–301.
Armour, C. J., and H. V. Thompson. 1955. Spread of myxomatosis in the
first outbreak in Great Britain. Annals of Applied Biology 43:511–
518.
Blanco, J. C., and R. Villafuerte. 1993. Factores ecológicos que influyen sobre las poblaciones de conejos: incidencia de la enfermedad hemorrágica. Technical report. Empresa de Transformación
Agraria S.A., Madrid.
Blas-Aritio, L. 1970. Vida y costumbre de los mustélidos Españoles.
Servicio de Pesca Continental, Caza y Parques Nacionales-Ministerio
de Agricultura, Madrid.
Blázquez, M. C., and R. Villafuerte. 1990. Nesting of the Montpellier
snake (Malpolon monspessulanus) inside rabbit warrens at Doñana
National Park (SW Spain): phenology and a probable case of communal nesting. Journal of Zoology 222:692–693.
Cabral, M. J., et al. 2005. Livro vermelho dos vertebrados de Portugal.
Instituto da Conservação da Natureza, Lisbon.
Cagnin, M., S. Moreno, G. Aloise, G. Garofalo, R. Villafuerte, P. Gaona,
and M. Cristaldi. 1998. Comparative study of Spanish and Italian terrestrial small mammal coenoses from different biotopes in Mediterranean peninsular tip regions. Journal of Biogeography 25:1105–
1113.
Callou, C. 2003. De la garenne au clapier. Étude archéozoologique
du lapin en Europe occidentale. Mémoires du Muséum national
d’Histoire naturelle, Paris.
Calvete, C., R. Villafuerte, J. Lucientes, and J. J. Osácar. 1997. Effectiveness of traditional wild rabbit restocking in Spain. Journal of Zoology
241:271–277.
Cerván Carmona, C. M., and F. Pardo Navarro. 1997. Dispersión de
semillas de retama (Retama sphaerocarpa, L. Boiss) por el conejo
(Oryctolagus cuniculus) en el centro de España. Doñana Acta Vertebrata 21:143–154.
Chapin, F. S., et al. 2000. Consequences of changing biodiversity. Nature
405:234–242.
Cowling, R. M., P. W. Rundell, B. B. Lamont, M. K. Arroyo, and M.
Arianoutsou. 1996. Plant diversity in Mediterranean-climate regions.
Trends in Ecology & Evolution 11:362–366.
Crawley, M. J. 1990. Rabbit grazing, plant competition and seedling
recruitment in acid grassland. Journal of Applied Ecology 27:803–
820.
Crawley, M. J., and J. Weiner. 1991. Plant size variation and vertebrate
herbivory: winter wheat grazed by rabbits. Journal of Applied Ecology 28:154–172.
Delibes, M. 1972. La caza en España. Alianza Editorial, Madrid.
Delibes, M., and F. Hiraldo. 1981. The rabbit as prey in the Iberian
Mediterranean ecosystem. Pages 614–622 in K. Myers and C. D.
MacInnes, editors. Proceedings of the I World lagomorph conference. University of Guelph, Guelph, Ontario, Canada.
Delibes-Mateos, M. 2006. Relaciones entre los cambios poblacionales
del conejo, la gestión cinegética, el hábitat y los depredadores: implicaciones para la conservación. PhD thesis. Universidad de Castilla
la Mancha, Ciudad Real, Spain.
Delibes-Mateos, M., S. M. Redpath, E. Angulo, P. Ferreras, and R. Villafuerte. 2007. Rabbits as a keystone species in southern Europe.
Biological Conservation 137:149–156.
Delibes-Mateos, M., P. Ferreras, and R. Villafuerte. 2008a. Rabbit populations and game management: the situation after 15 years of rabbit
haemorrhagic disease in central-southern Spain. Biodiversity and
Conservation 17:559–574.
Delibes-Mateos, M., E. Ramirez, P. Ferreras, and R. Villafuerte. 2008b.
In Translocations as a risk for the conservation of European rabbit
lineages. ORYX 42:259–264.
Dellafiore, C. M., S. Muñoz Vallés, and J. B. Gallego Fernández.
2006. Rabbits (Oryctolagus cuniculus) as dispersers of Retama
monosperma seeds in a coastal dune system. EcoScience 13:5–
10.
Di Castri, F., and H. A. Money. 1973. Mediterranean type ecosystems.
Origin and structure. Ecological studies 7. Chapman & Hall, London.
Dickman, C. R. 1999. Rodent-ecosystem relationships: a review. Pages
113–133 in G. R. Singleton, L. A. Hinds, H. Leirs, and Z. Zhang,
editors. Ecologically based management of rodent pests. Australian
Centre for International Agricultural Research, Canberra.
Eldridge, D. J., and R. Simpson. 2002. Rabbit (Oryctolagus cuniculus L.)
impacts on vegetation and soils, and implications for management
of wooded rangelands. Basic and Applied Ecology 3:19–29.
Fernández, C. 1993. Effect of the viral haemorrhagic pneumonia of the
wild rabbit on the diet and breeding success of the golden eagle
Aquila chrysaetos (L.). Terre et Vie 48:323–329.
Ferrer, M., and J. J. Negro. 2004. The near extinction of two large European predators: super specialists pay a price. Conservation Biology
18:344–349.
Galante, E., and M. C. Cartagena. 1999. Comparision of Mediterranean
dung beetles (Coleoptera: Scarabaeoidea) in cattle and rabbit dung.
Environmental Entomology 28:420–424.
Gálvez, L. 2008. El conejo europeo (Oryctolagus cuniculus) como especie ingeniera de los ecosistemas. PhD thesis. Universidad de Alcalá, Alcalá de Henares, Spain.
Gálvez, L., A. López-Pintor, J. De Miguel, G. Alonso, M. Rueda, S. Rebollo,
and A. Gómez-Sal. 2008. Ecosystem engineering effects of European
rabbits in a Mediterranean habitat. Pages 125–140 in P. C. Alves and
K. Hackländer, editors. Lagomorph biology: evolution, ecology and
conservation. Springer-Verlag, Berlin.
Garcı́a y Bellido, A. 1945. España y los españoles hace dos mil años
según la geografı́a de Strábon. Espasa-Calpe, Madrid.
Garcı́a-Fuentes, A., J. J. Muñoz-Rodrı́guez, and E. Cano-Carmona. 2006.
Alteraciones florı́sticas en los pastizales sometidos a altas densidades
de conejos. Revista del Colegio Oficial de Biólogos de Andalucı́a
5:2–5.
Gibb, J. A. 1990. The European rabbit, Oryctolagus cuniculus. Pages
116–120 in J. A. Chapman and J. E. C. Flux, editors. Rabbit, hares and
pikas: status survey and conservation action plan. IUCN/SCC Lagomorph Specialist Group, Information Press, Oxford, United Kingdom.
Gibb, J. A. 1993. Sociality, time and space in a sparse population of
rabbits (Oryctolagus cuniculus). Journal of Zoology 229:581–607.
Gómez-Sal, A., J. M. Rey-Benayas, A. López-Pintor, and S. Rebollo. 1999.
Role of disturbance in maintaining a savanna-like pattern in Mediterranean Retama sphaerocarpa shrubland. Journal of Vegetation Science 10:365–370.
Hansson, L. 1998. Local hot spots and their edge effects: small mammals
in oak-hazel woodland. Oikos 81:55–62.
Hiraldo, F. 1976. Diet of the Black Vulture (Aegypius monachus) in the
Iberian Peninsula. Doñana Acta Vertebrata 3:19–31.
Hiraldo, F., M. Delibes, and J. Calderón. 1979. El Quebrantahuesos
Gypaetus barbatus (L.). ICONA, Madrid.
INE (Instituto Nacional de Estadı́stica). 2006. Caza: piezas cobradas
por especie, número/peso/valor y año. INE, Madrid. Available from
http://www.ine.es (accessed January 2007).
Jaksic, F. M., and M. Delibes. 1987. A comparative analysis of food
niche relationships and trophic guild structure in two assemblages
of vertebrate predators differing in species richness: causes, consequences and correlations. Oecologia 71:461–472.
Johnson, C. N. 1996. Interactions between mammals and ectomycorrhizal fungi. Trends in Ecology & Evolution 11:503–507.
Jones, C. G., J. H. Lawton, and M. Shachack. 1994. Organisms as ecosystem engineers. Oikos 69:373–386.
Jordano, P., and E. W. Schubb. 2000. Seed disperser effectiveness: the
quantity component and patterns of seed rain for Prunus mahaleb.
Ecological Monographs 70:591–615.
Conservation Biology
Volume 22, No. 5, 2008
1116
Kolb, H. H. 1991. Use of burrows and movements by wild rabbits (Oryctolagus cuniculus) on an area of sand dunes. Journal of Applied
Ecology 28:879–891.
Kotliar, N. B. 2000. Application of the new keystone-species concept to
prairie dogs: how well does it work? Conservation Biology 14:1715–
1721.
Kotliar, N. B., B. W. Baker, A. D. Whicker, and G. Plumb. 1999. A critical
review of assumptions about the prairie dog as a keystone species.
Environmental Management 24:177–192.
Kufner, M. B. 1986. Tamaño, actividad, densidad relativa y preferencia
de hábitat de los pequeños y medianos mamı́feros de Doñana, como
factores condicionantes de su tasa de depredación. PhD thesis. Universidad Autónoma de Madrid, Madrid.
Lavorel, S., J. Canadell, S. Rambal, and J. Terradas. 1998. Mediterranean
terrestrial ecosystems: research priorities on global change effects.
Global Ecology and Biogeography 7:157–166.
Leigh, J. H., D. H. Wood, M. D. Holgate, A. Slee, and M. D. Stranger.
1989. Effect of rabbit and kangaroo grazing on two semi-arid grassland communities in central-western New South Wales. Australian
Journal of Botany 37:375–396.
Lovell, R. H., and S. C. Jarvis. 1996. Effect of cattle dung on soil microbial
biomass C and N in a permanent pasture soil. Soil Biology and
Biochemistry 28:291–299.
Malo, A. F., J. Lozano, D. L. Huertas, and E. Virgós. 2004. A change of
diet from rodents to rabbits (Oryctolagus cuniculus). Is the wildcat
(Felis silvestris) a specialist predator? Journal of Zoology 263:401–
407.
Malo, J. E., and F. Suárez. 1995. Herbivorous mammals as seed dispersers
in Mediterranean dehesa. Oecologia 104:246–255.
Malo, J. E., B. Jiménez, and F. Suárez. 1995. Seed bank regeneration in
small pasture gaps: the contribution of endozoochorous dispersal
by rabbits. Ecography 18:73–82.
Malo, J. E., B. Jiménez, and F. Suárez. 2000. Herbivory dunging and
endozoochorous seed deposition in a Mediterranean dehesa. Journal
of Rangeland Management 53:322–328.
Margalida, A., J. Beltrán, and J. Boudet. 2005. Assessing the diet of
nestling Bearded Vultures: a comparison between direct observation
methods. Journal of Field Ornithology 76:40–45.
Mills, S., M. E. Soule, and D. F. Doak. 1993. The keystone-species concept in ecology and conservation. BioScience 43:219–226.
Mittermeier, R. A., P. R. Gil, M. Hoffman, J. Pilgrim, T. Brooks, C. G.
Mittermeier, J. Lamoreux, and G. A. B. da Fonseca. 2005. Hotspots
revisited: earth’s biologically richest and most endangered terrestrial
ecoregions. Conservation International/CEMEX, Mexico City.
MMA (Ministerio de Medio Ambiente). 2008. Estrategia española para
la conservación y el uso sostenible de la diversidad biológica.
MMA, Madrid. Available from http://www.mma.es (accessed January 2008).
Moleón, M. 2007. El estudio del impacto de los predadores sobre las presas cinegéticas: un intento de compatibilizar caza y conservación.
Pages 743–794 in J. M. Barea-Azcón, M. Moleón, R. Travesı́, E.
Ballesteros-Duperón, J. M. Luzón, and J. M. Tierno de Figueroa,
editors. Biodiversidad y conservación de fauna y flora en ambientes
Mediterráneos. Sociedad Granatense de Historia Natural, Granada.
Monnerot, M., J. D. Vigne, C. Biju-Duval, D. Casane, C. Callou, C. Hardy,
F. Mougel, R. C. Soriguer, N. Dennebouy, and J. C. Mounolou. 1994.
Rabbit and man: genetic and historic approach. Genetics, Selection,
Evolution 26:167s–182s.
Moreno, S., and R. Villafuerte. 1995. Traditional management of scrubland for the conservation of rabbits Oryctolagus cuniculus and their
predators in Doñana Nacional Park, Spain. Biological Conservation
73:81–85.
Moreno, S., R. Villafuerte, S. Cabezas, and L. Lombardi. 2004. Wild rabbit
restocking for predator conservation in Spain. Biological Conservation 118:183–1993.
Muñoz, G. 1960. Anverso y reverso de la mixomatosis. Dirección General de Montes, Caza y Pesca Fluvial, Madrid.
Conservation Biology
Volume 22, No. 5, 2008
Rabbits and the Mediterranean Basin
Muñoz Reinoso, J. C. 1993. Consumo de galbulos de Sabina (Juniperus
phoenicea spp. turbinata Guss, 1891) y dispersión de semillas por
el conejo (Oryctolagus cuniculus) en el Parque Nacional de Doñana.
Doñana Acta Vertebrata 20:49–58.
Myers, N., R. A. Mittermeier, C. G. Mittermeier, G. A. B. da Fonseca,
and J. Kent. 2000. Biodiversity hotspots for conservation priorities.
Nature 403:853–858.
Oosterveld, P. 1983. Eight years of monitoring of rabbits and vegetation
development on abandoned arable fields grazed by ponies. Acta
Zoologica Fennica 174:71–74.
Osácar-Jiménez, J. J., J. Lucientes-Curdi, and C. Calvete-Margolles. 2001.
Abiotic factors influencing the ecology of wild rabbit fleas in northeastern Spain. Medical and Veterinary Entomology 15:157–166.
Palomares, F. 2001. Comparison of 3 methods to estimate rabbit
abundance in Mediterranean environment. Wildlife Society Bulletin
29:578–585.
Palomares, F. 2003. Warren building by European rabbit (Oryctolagus
cuniculus) in relation to cover availability in a sandy area. Journal
of Zoology 259:63–67.
Palomares, F., and M. Delibes. 1993. Key habitat for Egyptian Mongooses
in Doñana National Park, south-western Spain. Journal of Applied
Ecology 30:752–758.
Palomares, F., M. Delibes, E. Revilla, J. Calzada, and J. M. Fedriani. 2001.
Spatial ecology of Iberian lynx and abundance of European rabbits
in south-western Spain. Wildlife Monographs 148:1–36.
Petterson, D. A. 2001. The effects of the wild rabbit (Oryctolagus cuniculus) on soils and vegetation in semi-arid, south-eastern Spain.
PhD thesis. University of Leeds, Leeds, United Kingdom.
Piñol, J., J. Terradas, and F. Lloret. 1998. Climate warming, wildfire
hazard, and wildfire occurrence in coastal eastern Spain. Climatic
Change 38:345–357.
Power, M. E., D. Tilman, J. A. Estes, B. A. Menge, W. J. Bond, L. S.
Mills, G. Daily, J. C. Castilla, J. Lubchenco, and R. T. Paine. 1996.
Challenges in the quest for keystones. BioScience 46:609–620.
Priddel, D., N. Carlile, and R. Wheeler. 2000. Eradication of European
rabbits (Oryctolagus cuniculus) from Cabbage Tree Island, NSW,
Australia, to protect the breeding habitat of Gould’s petrel (Pterodroma leucoptera leucoptera). Biological Conservation 94:115–
125.
Real, J., and S. Mañosa. 1997. Demography and conservation of Western European Bonellis Eagle (Hieraaetus fasciatus) populations.
Biological Conservation 79:59–66.
Revilla, E., and F. Palomares. 2002. Does local feeding specialization
exist in Eurasian badgers? Canadian Journal of Zoology 80:83–93.
Revilla, E., F. Palomares, and N. Fernández. 2001. Characteristics, location and selection of diurnal resting dens by Eurasian badgers
(Meles meles) in a low density area. Journal of Zoology 255:291–
299.
Rogers, P. M., C. P. Arthur, and R. C. Soriguer. 1994. The rabbit in
continental Europe. Pages 22–63 in H. V. Thompson and C. M.
King, editors. The European rabbit. The history and biology of a
successful colonizer. Oxford Science Publications, Oxford, United
Kingdom.
Rueda, M. 2006. Selección de hábitat por herbı́voros de diferente
tamaño y sus efectos sobre la vegetación. PhD thesis. Universidad
de Alcalá, Alcalá de Henares, Spain.
Sánchez-Piñero, F., and J. M. Ávila. 1991. Análisis comparativo de
los Scarabaeoidea (Coleoptera) coprófagos de las deyecciones de
conejo (Oryctolagus cuniculus (L.)) y de otros mamı́feros: estudio
preliminar. Eos 67:23–24.
Smith, A. T., and J. M. Foggin. 1999. The plateau pika (Ochotona curzoniae) is a keystone species for biodiversity on the Tibetan plateau.
Animal Conservation 2:235–240.
Soriguer, R. C. 1980. Ciclo anual de parasitismo por pulgas y garrapatas en el conejo de campo (Oryctolagus cuniculus) en Andalucı́a Occidental, España. Revista Ibérica de Parasitologı́a 40:539–
550.
1117
Delibes-Mateos et al.
Soriguer, R. C. 1981. Consideraciones sobre el efecto de los conejos
y los grandes herbı́voros en los pastizales de la Vera de Doñana.
Doñana Acta Vertebrata 10:155–168.
Soriguer, R. C. 1986. The rabbit as a plant seed disperser. Mammal
Review 16:197–198.
Symeonakis, E., A. Calvo-Cases, and E. Arnau-Rosalen. 2007. Land use
change and land degradation in southeastern Mediterranean Spain.
Environmental Management 40:80–94.
Taberlet, P., L. Fumagalli, A. G. Wust-Saucy, and J. F. Cosson. 1998.
Comparative phylogeography and postglacial colonization routes in
Europe. Molecular Ecology 7:453–464.
Thompson, H. V., and C. M. King. 1994. The European rabbit. The
history and biology of a successful colonizer. Oxford University
Press, Oxford, United Kingdom.
Tilman, G. D. 1999. Diversity by default. Science 283:495–496.
Valkama, J., et al. 2005. Birds of prey as limiting factors of gamebird
populations in Europe: a review. Biological Reviews 80:171–203.
Valverde, J. A. 1967. Estructura de una comunidad de vertebrados
terrestres. Monografı́as de la Estación Biológica de Doñana. CSIC,
Madrid.
van der Wal, R., H. van Wijnen, S. van Wieren, O. Beucher, and D. Bos.
2000. On facilitation between herbivores: how Brent Geese profit
from brown hares. Ecology 81:969–980.
Verdú, J. R., and E. Galante. 2004. Behavioural and morphological
adaptations for a low-quality resource in semi-arid environments:
dung beetles (Coleoptera, Scarabaeoidea) associated with the European rabbit (Oryctolagus cuniculus L.). Journal of Natural History
38:705–715.
Verdú, J. R., and E. Galante. 2002. Climatic stress, food availability and
human activity as determinants of endemism patterns in the Mediterranean region: the case of dung beetles (Coleoptera, Scarabaeoidea)
in the Iberian Peninsula. Diversity and Distributions 8:259–274.
Villafuerte, R., and M. Delibes-Mateos. 2007. El conejo. Pages 490–491
in L. J. Palomo, J. Gisbert, and J. C. Blanco, editors. Atlas y Libro
Rojo de los Mamı́feros Terrestres de España. Dirección General para
la Biodiversidad-SECEM-SECEMU, Madrid.
Villafuerte, R., C. Calvete, J. C. Blanco, and J. Lucientes. 1995. Incidence
of viral hemorrhagic disease in wild rabbit populations in Spain.
Mammalia 59:651–659.
Viñuela, J., and J. P. Veiga. 1992. Importance of rabbits in the diet and
reproductive success of black kites in south-western Spain. Ornis
Scandinavica 23:132–138.
Virgós, E., S. Cabezas-Dı́az, and J. Lozano. 2007. Is the wild rabbit (Oryctolagus cuniculus) a threatened species in Spain? Sociological constraints in the conservation of species. Biodiversity and Conservation
16:3489–3504.
Vitousek, P. M., C. M. D’Antonio, L. L. Loope, M. Rejmanek, and R.
Westbrooks. 1997. Introduced species: a significant component of
human-caused global change. New Zealand Journal of Ecology 21:1–
16.
Ward, D. 2005. Reversing rabbit decline: one of the biggest challenges for nature conservation in Spain and Portugal. Technical
report. World Conservation Union, Gland, Switzerland. Available
from
http://www.iucn.org/en/news/archive/2005/12/report.pdf
(accessed September 2007).
Watt, A. S. 1981. Further observations on the effects of excluding rabbits from grassland in East Anglian Breckland: the pattern of change
and factors affecting it (1936–73). Journal of Ecology 69:509–
536.
Willot, S. J., A. J. Miller, L. D. Incoll, and S. G. Compton. 2000. The
contribution of rabbits (Oryctolagus cuniculus L.) to soil fertility in
semi-arid Spain. Biology and Fertility of Soils 31:379–384.
Wood, D. H. 1988. Estimating rabbit density by counting dung pellets.
Australian Wildlife Research 15:665–671.
Conservation Biology
Volume 22, No. 5, 2008