ISSN 1827-9635 (print) © Firenze University Press 
ISSN 1827-9643 (online) www.fupress.com/ah

Acta Herpetologica 8(1): 47-52, 2013

Going out tonight? When insular Hierophis viridiflavus breaks the Whip 
Snakes Rules

Delaugerre Michel-Jean

Conservatoire du littoral, 3, rue Luce de Casabianca F20200 Bastia, France. E-mail: m.delaugerre@conservatoire-du-littoral.fr

Submitted on: 2012, 11th November; revised on: 2013, 20th January; accepted on: 2012, 5 th February.

Abstract. Hierophis viridiflavus has a strong diurnal rhythm as demonstrated by many field studies. It belongs to the 
“Whip snakes” characterized by slender bodies, large eyes, high speed, saurophagy and diurnality. On Giraglia island 
(Corsica) the snakes do forage also nightly. This unexpected shift in the circadian rhythm might be related to a local 
adaptation to trophic requirements.

Keywords. Activity pattern shift, microinsular adaptation, Corsica, Mediterranean, nocturnal.

In insular contexts, characterized by genetic isola-
tion and peculiar ecological constraints, animals often 
display geographic variations affecting their morphology 
such as body size and proportions, pigmentation, pattern 
(Case, 1978; Lomolino, 2005; Meiri, 2007; Pafilis et al., 
2009; Novosolov et al., 2012); biology and ecology such 
as diet and foraging modes, ecological interactions, micro 
habitat selection and many other features of their life his-
tory traits and behaviour (Pérez-Mellado and Corti, 1993; 
Traveset and Sáez, 1997; Van Damme, 1999; Zuffi, 2001; 
Filippi et al., 2003; Olesen and Valido, 2004; Herrel et al., 
2008; Delaugerre et al. 2012).

According to Shine (1980) “whip snakes” are con-
spicuous elements of the terrestrial snake fauna in most 
parts of the world. These phylogenetically unrelated taxa 
(families Colubridae and Elapidae), characterized by con-
vergent evolution, display morphological, ecological and 
behavioural traits such as slender bodies, long tails, large 
eyes, alertness, diurnality, terrestriality, saurophagy, ovi-
parity and high speed. A broad ecological study of the 
Western Whip Snake Hierophis viridiflavus (Lacépède, 
1789) in central Italy (Capula et al., 1997) partially cor-
roborated Shine’s (1980) views.

We report and discuss preliminary data regarding the 
micro insular activity pattern shift of the Western Whip 
Snake, occurring on Giraglia Island.

Giraglia Island (43°01’30”N; 9°24’24”E; 10 hec-
tares, 65 m a.s.l., distance from the main island 1.4 km) 
is located at the northernmost point of Corsica (Fig. 
1). It was severed from the coast by sea level rise some 
5000 years ago (Lambeck and Bard, 2000). The dense 
and low vegetation is dominated by Allium commutatum 
and Halimione portulacoides (with a total of 60 vascular 
plants, Rivière et al., 2012). It hosts two geckos Euleptes 
europaea and Tarentola mauritanica, one Lacertid Podar-
cis tiliguerta pardii and one Colubrid Snake Hierophis 
viridiflavus (Lanza and Brizzi, 1974). Except for T. mau-
ritanica, the Giraglia herpetofauna is supposed to be 
native. The island is rat (and mammal) free. Nesting birds 
are Calonectris diomedea, Larus michaellis (since the 90’s), 
Phalacrocorax aristotelis desmarestii, Apus pallidus and 
Columba livia; Falco tinnunculus and Falco peregrinus 
often visit the island. Giraglia has hosted a small human 
settlement (2-5 men and few cattle) since the end of the 
16th century until the end of the 20th century when the 
lighthouse has been automated. Included in a site of com-
munity importance (EU), the island is a protected area. 
The public access is forbidden, except for the lighthouse 
maintenance and biodiversity monitoring.

Nocturnal investigations (initially focussed on 
gecko’s monitoring) were performed on 12 September 
2000, on 5 and 9 August 2012 and on 6 October 2012. 



48 Delaugerre Michel-Jean

In August 2012 additional data (Table 1) were gathered 
by naturalists monitoring Cory’s Shearwater. The moon-
light was very bright in 2000 and sampling occurred 
during all moon phases in 2012. While rocky outcrops 
were thoroughly investigated with head lamp, Western 
Whip Snakes were seen, foraging from 19:30 h to 2:00 
h. They were actively crawling on rocks, on footpaths 
and on vegetation, tongue flicking while slowly explor-
ing the substrate surfaces and crevices. Two snakes were 
seen in 2000 and seventeen in 2012. In 2000 both were 
sub-adults; in 2012 all age classes were represented, with 
a majority of young and youngsters (Table 1). One adult 
was also observed inactive under exsiccated plants.

During the last fifteen years, many Italian and French 
publications have been devoted to various aspects of the 
biology and ecology of H. viridiflavus. These studies have 
been performed at different latitudes, from Vendée on 
the French Atlantic coast, Switzerland, to Northern and 
Central Italy. In all these papers the activity pattern of 
this snake is considered as diurnal. Capula et al. (1997) 
assessed a bimodal (and lower) daily activity in sum-
mer. Lelièvre et al. (2010, 2011) confirmed the diurnal 
habits of this thermophilous species, even radio tracked 
animals were only recorded during the daytime, so did 
Ciofi and Chelazzi, (1991) and Scali et al. (2008). Ciofi 
and Chelazzi (1994), who recorded activity rhythms 24 
h long, also stated that “Coluber viridiflavus was defi-
nitely diurnal; the primary and secondary shelters were 
used overnight…” The recent synthesis (Vanni and Nis-
tri, 2006; Vanni and Zuffi, 2010) asserted its diurnal-

ity; only (Santos et al., 2010) stated “Sin embargo, no es 
extraño observar actividad crepuscular en los meses más 
calurosos”(however, it is not unusual to see crepuscular 
activity in the warmer months). 

Although no nocturnal habits were documented 
in literature, could these studies, performed mainly by 
“diurnal herpetologists”, with visual encounters and 
some radio tracking performed only in the daytime, have 
missed a point? Our field data have been investigated. 
Intensive nocturnal searches (224 hrs) were performed 
in Corsica (and Sardinia), for geckos in rocky habitats 
and, to a lesser extent, for amphibians in wetlands. Those 
investigations occurred in many localities of Corsica and 
also on the satellite islands where the density of the West-
ern Whip Snake is very high, as on Lavezzu island (Table 
2). Except for Giraglia, only one observation of true noc-
turnal activity has been recorded (Bonifacio, 13 June 
1983, 21:30 h, dark moon, air temperature 20.8 °C, juve-
nile snout vent length 33 cm, tail 8 cm). A crepuscular 
sighting of a young animal has also been recorded on 16 
July 2006 (Cape Corse, Moulin Mattei).

The nocturnal activity of H. viridiflavus does not 
occur or is very rare. This snake appears to have a strong 
rhythm for a specific diel activity pattern despite sea-
sonal changes in temperature (Gibbons and Semlitsch, 
1987) and latitudinal variations. Among Western Euro-
pean snakes (Corti et al, 2010; Salvador and Marco, 
2010), most diurnal species (16) are variable; they adjust 
their circadian rhythm to season and environmental tem-
perature with crepuscular or nocturnal foraging in sum-

Figure 1. The Giraglia island seen from the North-East. © F. Rombaldi/assoc. Finocchiarola.



49Night activity in Hierophis viridiflavus

mer, whereas other species are strictly diurnal (eight) or 
nocturnal (two). These later species (including H. vir-
idiflavus) having supposedly an activity pattern “geneti-
cally determined to the extent that their response to the 
light-dark is endogenous and invariable” (Gibbons and 
Semlitsch, 1987). The nocturnal activity reported on 
Giraglia island is an outstanding exception. There, young 
and also adult snakes (Corsican Whip Snakes are small 
sized according to Cheylan, 1992 and Vanni and Zuffi, 
2010) forage also nightly, and not only during the hot-
test months. This enlargement of the activity spectrum 
isn’t related to the moon phase, nor to the light intensity. 
Although these preliminary data will need further study, 
they raise an array of questions.

Taking into account, at a broad level, the value of a 
phylogenic perspective in understanding patterns of evo-
lution in behavior, morphology and physiology (Autum 
et al, 2002) and also the suggested possibility that noc-
turnality might be the primitive condition of squamates 
(Sites et al., 2011), we consider that the observed enlarge-
ment of the temporal niche probably results of a rather 
recent local insular microevolution.

Hypotheses for possible advantages of such nocturnal 
shift may be related to: 1) avoidance of diurnal predators; 
2) avoidance of high temperatures; 3) easier acquirement of 
preferred/available food at night; or combination of these 
factors (Crawford, 1934; Gibbons and Semlitsch, 1987). 

1) Avoidance of diurnal predators. Falco tinnunculus 
is well known to predate young and subadult snakes. But 
empirical observations (to be confirmed) suggest that 
whip snakes of all age classes are also pretty active in 
the daytime. Furthermore, during the Larus michahell-
is nesting season, the F. tinnunculus avoids the island. 
Nevertheless if a strong interaction between whipsnakes 
and this raptor is not likely to occur nowadays, we can-
not discard its occurrence during the past history of the 
island. 2) Avoidance of high temperatures. H viridifla-
vus is a thermophilous species and the island is complex 
enough (rocky outcrops, soil, low but thick vegetation) 
to provide natural shelters with medium temperatures. 
3) Easier acquirement of prey. The prey items available 
are mostly Podarcis tiliguerta lizards (high density), the 
nocturnal gecko Euleptes europaea, Invertebrates and 
presumably passerine birds in spring migration. Should 
the microinsular limitation of prey type diversity lead to 
increase the intraspecific competition for food between 
young and adult snakes and thus favor an enlargement 
of the temporal niche for the younger snakes? (see Lui-
selli, 2006 for tropical vipers in a context of habitat alter-
ation). But these intraspecific interactions are less likely 
to occur with high density (= availability) of the main 
food resource (lizards). An alternative hypothesis would 
be a local adaptation to a peculiar behavior of the prey. 
On Giraglia island, Podarcis lizards are often resting by 

Table 1. Nocturnal activity of Hierophis viridiflavus sighted (or captured) on Giraglia Island on 2012 (5 and 9 August and 6 October M. 
Delaugerre; 12 to 22 August A. Prudor and N. El Ksabi). In August night air temperature range 23-25 °C; relative hygrometry 73-82%; in 
October night air temperature range 18-19 °C; relative hygrometry 68-83%.

Date
Universal 

Time
Micro habitat Approximative age class

SVL 
(cm)

Tail 
(cm)

Weight (g)
Body 

temperature 
(°C)

05/08/12 21:43 Lighthouse pavement Juvenile 26.0 8 4.2
05/08/12 1:10 Rocks Juvenile
05/08/12 1:40 Rocks Adult 69.0 24
09/08/12 20:07 Footpath Adult 71.0 26
09/08/12 21:12 Stone wall Sub adult 55.6 20 38
12/08/12 19:40 Stone wall Sub adult
13/08/12 20:30 Vegetation Sub adult
14/08/12 23:49 Lighthouse pavement Adult 72.5 23.5
15/08/12 0:00 Lighthouse pavement Juvenile
15/08/12 22:15 Footpath Juvenile
17/08/12 19:30 Footpath Juvenile
19/08/12 20:00 Vegetation Juvenile
19/08/12 20:40 Vegetation Juvenile
21/08/12 23:15 Footpath Sub adult
06/10/12 18:50 Stone wall Sub adult 44.0 14.0 17 28.0
06/10/12 18:45 Rocks Juvenile 29.0 9.5 6.5 25.8
06/10/12 23:25 Footpath Sub adult 50.5 19.5 24 26.0



50 Delaugerre Michel-Jean

Table 2. Nocturnal investigations performed in Corsica (and Sardinia) from 1980 to 2012. Sighting per Unit Effort (SPUE) = n / (TO)100; 
where n = number of H. viridiflavus sighted; T = duration of searches in minutes; O = number of observers. 
Observers: if n = 1= M-J. Delaugerre and M. Biaggini (Caprera 2012, Lavezzu 2010, 2011, 2012), Ch.-H. Bianconi (Gargalu 1985); C. Corti 
(Caprera 2012, Lavezzu 2010, 2011, 2012); F. Grita (Lavezzu 2010, 2012), P. Lo Cascio (Caprera 2012, Lavezzu 2010, 2012). Some of the 
Giraglia data of Tab 1 are not reported here because SPUE could not be calculated.

Locality Year Month
N minutes 

prospection
N obs.

N minutes 
observation

Snakes  
sighted

SPUE

Corsican satellite islands
Giraglia island (N Corsica) 2000 9 360 1 360 2 0.556
Giraglia island (Corsica) 2012 8 406 1 406 5 1.232
Giraglia island (Corsica) 2012 10 260 1 260 3 1.154
Lavezzu island (S Corsica) 1982 5 300 1 300 0 0.000
Lavezzu island (S Corsica) 1984 9 120 1 120 0 0.000
Lavezzu island (S Corsica) 2010 6 275 2 550 0 0.000
Lavezzu island (S Corsica) 2011 6 427 1 427 0 0.000
Lavezzu island (S Corsica) 2012 6 180 4 720 0 0.000
Mezzumare island (W Corsica) 2011 6 180 1 180 0 0.000
Mezzumare island (W Corsica) 2012 8 213 1 213 0 0.000
Gargalu island (W Corsica) 1985 4 530 2 1060 0 0.000
Gargalu island (W Corsica) 1990 7 505 1 505 0 0.000

Corsica main island
Trinité (Bonifacio, S) 1983 6 300 1 300 1 0.333
Acciola (Sartene, SW) 1980 5 60 1 60 0 0.000
Conca-Senetosa (SW) 1986 8 180 1 180 0 0.000
Pianottoli (S) 1986 8 120 1 120 0 0.000
Galeria (W) 1981 5 60 1 60 0 0.000
Galeria (W) 1983 4 60 1 60 0 0.000
Galeria (W) 1982 5 60 1 60 0 0.000
Galeria (W) 1985 4 180 1 180 0 0.000
Galeria (W) 1985 7 180 1 180 0 0.000
Galeria (W) 1986 4 130 1 130 0 0.000
Scandola (W) 1982 5 2105 1 2105 0 0.000
Scandola (W) 1982 6 1465 1 1465 0 0.000
Scandola (W) 1983 4 595 1 595 0 0.000
Scandola (W) 1983 6 490 1 490 0 0.000
Scandola (W) 1985 7 100 1 100 0 0.000
Villanova (Ajaccio, W) 1981 5 810 1 810 0 0.000
Villanova (Ajaccio, W) 1981 6 125 1 125 0.000
Piana (W) 1981 5 60 1 60 0 0.000
M.on Forestière Lumio (1000m) 1981 5 60 1 60 0 0.000
A Serra  (Calvi, W) 1981 5 60 1 60 0 0.000
Lucciana (NE) 1985 4 60 1 60 0 0.000
Capandula (Cap Corse, N) 2012 8 270 1 270 0 0.000

Sardinia
Itiri (Sardinia) 1982 6 90 1 90 0 0.000
Caprera island (Maddalena, N) 2012 5 240 3 720 0 0.000

Sum  in minutes 11,616 13,441
Sum in hours 224



51Night activity in Hierophis viridiflavus

night in very exposed spots, not hidden in refuges, while 
E. europaea, a slow moving gecko, forages on rock sur-
faces. Snakes might have learned a way to easily pick 
some preys by night. If so, it would mean an important 
ecologic change in an evolutionary perspective: the quick 
pursuit foraging strategy (Capula et al., 1997), relying 
on diurnal vision, being replaced by a slow search con-
ducted by nocturnal vision or/and by the use of chem-
osensory cues. Chemical scents would be used for the 
localization of the prey, as males are able to do for trail-
ing and sexually discriminate conspecifics (Fornasiero et 
al., 2007). In snakes, saurophagy is compatible with noc-
turnality, for instance in Coronella and Macroprotodon 
(Cheylan, 1986). As stated by Shine (1980): “Apart from 
Demansia, the only Australian elapids that definitely are 
known to feed primarily on lizards (> 70% of the diet) 
are small fossorial nocturnal species… All of these fos-
sorial saurophagous snakes capture their prey at night 
when the lizards are inactive (an African elapid… for-
ages in the same way…). Prey items probably are located 
by scent… This foraging strategy is fundamentally dif-
ferent from that of the whipsnakes, which locate their 
prey items visually, during the day, and capture them by 
direct chasing.” 

The expression of adaptative “inventiveness” is highly 
stimulated in microinsular context, is that the reason why 
the Giraglia Island’ H. viridiflavus have broken the Whip 
Snakes Rules?

ACKNOWLEDGMENTS

The access to the island was permitted by the Préfecture 
de Haute-Corse and the “phares et balises” authorities. Collec-
tion permits were issued by the Dreal Corse. Thanks to Aurélien 
Prudor and Nory El Ksaby for their interest and valuable help 
in the field. Thanks to Claudia Corti for the experienced com-
ments on the manuscript and to the editor and the reviewers.

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	Riccardo Castiglia1,*, Alexandra M.R. Bezerra2, Oscar Flores-Villela3, Flavia Annesi1, Antonio Muñoz4, Ekaterina Gornung1
	Polydactyly in the Tyrrhenian wall lizard (Podarcis tiliguerta)

	Antigoni Kaliontzopoulou1,*, Daniele Salvi1, Verónica Gomes1, João P. M. C. Maia1,2,3, Panagiotis Kaliontzopoulos4
	Book Review: 
	Roberto Sindaco, Alberto Venchi, Cristina Grieco. The Reptiles of the Western Palearctic. 2.
	Annotated checklist and distributional atlas of the snakes of Europe, North Africa, Middle East and Central Asia, with an update to the Vol. 1. 

	Edoardo Razzetti
	ACTA HERPETOLOGICA
	Journal of the Societas Herpetologica Italica