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Acta Herpetologica 5(2): 199-205, 2010

Evidence of tail autotomy in the European plethodontid 
Hydromantes (Atylodes) genei (Temmick and Schlegel, 1838) 
(Amphibia: Urodela: Plethodontidae)

Antonio Romano1,*, Felix Amat2, Xavier Rivera3, Giuseppe Sotgiu4, Salvador 
Carranza5

1 Dipartimento di Biologia, Università di Roma “Tor Vergata”, Via della Ricerca Scientifica, I-00133 
Rome, Italy. Corresponding author. E-mail: antonioromano71@gmail.com
2 Àrea d’Herpetologia, Museu de Granollers – Ciències Naturals, Francesc Macià 51, E-08403, 
Granollers, Catalonia, Spain. E-mail: amatfelix@yahoo.co.uk
3 Societat Catalana d’Herpetologia Museu de Zoologia, Passeig Picasso s/n, E-08003, Barcelona, Spain. 
E-mail: xavirivera@yahoo.es
4 No profit Naturalistic Association Zirichiltaggi - Sardinia Wildlife Conservation, Strada Vicinale 
Filigheddu 62/C, I-07100, Sassari, Italy. E-mail: sotgiuseppe@hotmail.com
5 Institut de Biologia Evolutiva (CSIC-UPF), Passeig Marítim de la Barceloneta, 37-49, E-08003, Barce-
lona, Spain. E-mail: salvador.carranza@ibe.upf-csic.es

Submitted on: 2010, 5th May; revised on: 2010, 18th October; accepted on: 2010, 27th October.

Abstract. Caudal autotomy is a defensive mechanism widely adopted by lungless sala-
manders (Plethodontidae) from the New World. In contrast, in Europe, this mecha-
nism was not described until very recently for just one Sardinian species, Hydroman-
tes (Speleomantes) sarrabusensis. We report on tail autotomy observed in another spe-
cies from the same island, Hydromantes (Atylodes) genei. In Europe, self-amputation 
of the tail seems to be restricted to some plethodontids inhabiting Sardinia, while con-
tinental species do not exhibit analogous antipredator strategies. 

Keywords. Autotomy, Hydromantes, Plethodontid.

Autotomy is the ability to cast off, spontaneously or by reflex, a part of the body and, 
in herpetology, it usually refers to the breakage and loss of the tail. Autotomy is a wide-
spread defence against predators among invertebrates and vertebrates (see references in 
Cooper et al., 2004). 

Salamander antipredator strategies include autotomy among the suites of behavioural 
and morphological traits employed against predators and competitors (Brodie, 1983; Steb-
bins and Cohen, 1995). Such anatomical adaptation evolved in some plethodontids and 
salamandrids from an initial strategy based on redirecting the attack by predators to the 
body and/or the head to the tail by means of adopting a defensive posture (Brodie, 1977).



200 A. Romano et alii

Morphological diversification in skeletal, tongue and digital characteristics have all 
played an important role as diversification drivers in the large adaptive radiation of the 
family Plethodontidae, the most remarkable among salamanders, embracing from trog-
lodytic species to entirely arboreal ones (Wake and Larson, 1987). There is some evi-
dence that supports a complex pattern of independent origins of coevolved traits (Wake, 
1991). One of the most surprising traits, the ability to autotomize and regenerate the 
tail as defensive behaviour, has received little attention in evolutionary studies (Mueller 
et al., 2004). Among plethodontids, which are distributed predominantly in the Ameri-
cas (Wake, 1966; AmphibiaWeb, 2010), all members of the tropical radiation, including 
the neotropical genus Bolitoglossa, and a few species of other American genera (Ensati-
na, Hemidactylium and Batrachoseps) have specialized region at the base of the tail that is 
related to autotomy but many plethodontids that do not have specialized autotomy zones 
nevertheless are capable of autotomy (for a detailed account see Wake and Dresner, 1967).

The genus Hydromantes occurs in western North America (California; see USGS 
National Amphibian Atlas, 2009) and in central Mediterranean Europe. In particular, Euro-
pean plethodontids occur on the Mediterranean island of Sardinia (five species) and in 
peninsular Italy and a small southern-eastern portion of France (three species; Sindaco et 
al., 2006; Carranza et al., 2008). The North American Hydromantes belong to the subge-
nus Hydromantes, the mainland Europe species and four of the five Sardinian species are 
ascribed to the subgenus Speleomantes and a species inhabiting the southwest of Sardinia to 
the subgenus Atylodes. All three subgenera have sometimes been considered as full genera 
as a result of the large geographical disjunction that exists between western North America 
and Italy, but according to both the morphological differences and especially the low level 
of genetic differentiation that exists within the genus Hydromantes it is considered here that 
it is more appropriate to treat them as subgenera (see et al., 2005 for the taxonomic debate; 
Lanza et al., 2006; Wake; Crochet, 2007 for the alternative use of both terms; Carranza et 
al., 2008 and van der Meijden et al., 2009 for genetic differentiation within Hydromantes). 

Autotomy has been reported for European species only recently (Favelli et al., 2007) 
in the Sardinian Hydromantes (S.) sarrabusensis (Lanza, Leo, Forti, Cimmaruta, Caputo 
and Nascetti, 2001). 

During fieldwork carried out in Sardinia in 2006, we studied a population of Hydro-
mantes (A.) genei (Temminck and Schlegel, 1838), inhabiting a mine gallery near S. Gio-
vanni’s cave (Domusnovas, Carbonia-Iglesias). Each animal was measured and sexed and 
immediately released at the sampling site. During the handling of the specimens, tail 
autotomy was recorded in a subadult salamander (Fig. 1). The salamander, after twisting 
movements of the tail, lost a small portion of its distal part without losing blood. In the 
same population we observed other salamanders with regenerated tails. 

Since the plethodontid tail has locomotor, respiratory, behavioural and food storage 
functions (Wake and Dresner, 1967), its autotomy can be highly costly and therefore it 
plays an important role in the survival of the salamanders. Tail autotomy represents a loss 
of fat and protein (energy), both that are stored in the tail and represent the main source 
of energy in the tail regrown process, however making possible constraints, for instance, 
to the reproductive input (Maynard Smith and Parker, 1976; Bernardo and Agosta, 2005) 
and may impose other social costs, such as reduction in fighting ability (Wise and Jaeger, 
1998). Indeed, even in species which are highly specialised for caudal autotomy these very 



201Evidence of tail autotomy in the European plethodontid

Figure 1. Specimen of Hydromantes (A.) genei, showing tail autotomy: a. the salamander before autotomy; 
b. the same salamander after caudal autotomy; c. close-up of the autotomised tail; note that just the tail tip 
tail was shed.



202 A. Romano et alii

rarely drop their tails unless the situation is life threatening (Beneski, 1989). An autotom-
ic plethodontid observed by Favelli et al. (2007) used the fingers of the person handling 
the animal as a fulcrum to break its tail. To the contrary, the salamander we observed was 
free on the palm when autotomised its tail. Furthermore, as may be noted in Fig.1, the 
shed portion of the tail was very small. The loss of small portion of distal part of the tail 
reduces the disadvantage previously mentioned. The modality of caudal autotomy that was 
observed could be considered a case of “economy of autotomy”, which has been known for 
many years also in some reptiles (e.g., Woodland, 1920; Bustard, 1968; Cooper et al., 2009). 

The degree of specialisation for defensive tail loss varies among different Plethodon-
tids lineages. Some of them have highly specialised tail morphologies with basal con-
strained tails (Ensatina and Hemidactylium) associated with adult terrestrial life. In those 
species, the breakage includes almost the entire tail to ensure a large portion of food, dis-
couraging predators to attack the salamander (Wake and Dresner, 1967). Other lineages 
do not posses a localised breakage plane in their tail but have just developed wound heal-
ing capabilities. Finally, other lineages have no specialisation for caudal loss and their tails 
simply break mechanically as found in semi aquatic desmognathines and non-neotenic 
spelerpines (Wake and Dresner, 1967). 

In the genus Hydromantes (i.e., European cave salamanders and the three Californian 
species) tail autotomy is rare. In all American plethodontids exhibiting autotomy, rupture 
occurs between, rather than through, vertebrae as in lizards (see Stebbins and Choens, 
1995). Intervertebral breakage was confirmed also for the Sardinian species H. (S.) sar-
rabusenis (Favelli et al., 2007) and, likely, intervertebral breakage occurs also in H. (A.) 
genei. Despite the fact that tail regeneration after accidental breakage has been reported 
for some European mainland populations of Hydromantes (Salvidio, 1997), tail autotomy 
is only known to occur in the Sardinian species H. (S.) sarrabusensis (Favelli et al., 2007) 
and H. (A.) genei (this note). This difference among continental and island plethodon-
tids cannot be tested due to absence in research effort on H. ambrosii, H. italicus, and H. 
strinatii because these mainland species are more studied than their island congeners (cf. 
Lanza et al., 2006) and specific tests conducted to assess the occurrence of tail autotomy 
in continental plethodontids gave always negative results (Lanza et al., 2006). 

The tail plays an important role for climbing as it has been demonstrated for arbo-
real and saxicolous American salamanders of medium sizes (Wake, 1966) but not for 
small sized species (Alberch, 1981). With respect to the body dimension, in Hydromantes 
(A.) genei and H. (S.) sarrabusensis the largest sex presents an adult size of up to 124 mm, 
which is smaller than other Sardinian plethodontids (up to 127 mm for the smaller sex 
and up to 150 for the largest one) and comparable to the size of mainland species (up to 
128 mm) (see Lanza et al., 2007). However the actual differences in size among Hydro-
mantes species (less than 20%) are not comparable to size differences that exist among 
medium size and miniaturised salamanders (more than 100%) of the supergenus Bolito-
glossa (Alberch, 1981).

European Hydromantes are cave-adapted species [with the exception of H. (S.) sarra-
busensis] characterised by possessing large and webbed hands and feet that most probably 
are an adaptation to manoeuvre on the wet, smooth walls of caves (Lanza, 1991), as has 
been reported for other plethodontids species adapted to similar environmental condition 
(e.g., Chiropterotriton magnipes, Jaekel and Wake, 2007). Furthermore, the positive allom-



203Evidence of tail autotomy in the European plethodontid

etric lengthening of the tail (meaning that larger individuals have proportionately longer 
tail), has a similar adaptive significance because Cave salamanders use their prehensile 
and sensitive tail largely during climbing (Lanza, 1991). The loss of the tail can thus likely 
affect their climbing performance. It would be of particular interest to investigate if the 
two Sardinian taxa exhibiting caudal autotomy [H. (A.) genei and H. (S.) sarrabusensis] 
are more terrestrial than climbers or if they are too small to be affected by the loss of the 
tail on their climbing abilities. However little ecological information is available to allow 
any preliminary conclusions. Hydromantes (S.) sarrabusensis is a terrestrial salamander liv-
ing on the ground in a granitic area without caves of south-eastern Sardinia (Lanza et al., 
2006) and, consequently, it can be hypothesised that it climbs less than the other Euro-
pean cave-adapted species. Thus, in this species, the tail loss would affect its movement 
capacity less than in a cavernicolous species. On the contrary, Hydromantes (A.) genei, 
although it also inhabits humid forested areas in the vicinity of streams, it is mainly a cav-
ernicolous species, but no data are available to establish if this salamander spends more 
time on the ground than other European plethodontids. 

Hydromantes (A.) genei is the sister and basal clade to all the other European cave sala-
manders and its ancestor colonised Sardinia in the late Miocene (9 Million of year ago, Ma), 
while H. (S.) sarrabusenis belongs to a different lineage of eastern Sardinian plethodontids 
and originated approximately 5 Ma (Carranza et al., 2008; van der Meijden et al., 2009). 

Studies on the evolution of the caudal autotomy, could elucidate if this defensive 
trait was acquired independently by these two species and therefore can be considered a 
convergence. In Hydromantes (A.) genei two distinct lineages (A and B), showing a deep 
genetic divergence, have been recognised (Lanza et al., 1995; Carranza et al., 2008; van 
der Meijden et al., 2009). We only observed tail autotomy in members of lineage A. Fur-
ther studies need to verify the existence of tail autotomy in the other lineage and in other 
Sardinian plethodontid species, whose ecological traits are substantially unknown. Indeed, 
consideration should be given to conspecific populations, or populations of closely related 
species, which are exposed to diverse predator pressures and may exhibit different level of 
tail autotomy as defensive behaviour (Cooper et al., 2004). 

ACkNOWLEDGEMENTS

Specimens were handling under permission of from the ‘Ministero dell’Ambiente e della Tute-
la del Territorio e del Mare’ (permit reference: DPN/2D/2006/7546). This study was supported by 
grant CGL2009-11663 from the Minsterio de Ciencia e Innovación and grant 2009 SGR 1462 from 
the Generalita de Catalunya to SC. We would like to thank David Wake and one anonymous referee 
for useful suggestions during the revision of the manuscript.

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