Corucia of the Solomon Islands, Most Amazing of Skinks

SKINKS! Again.

A captive Corucia in a commercial collection. Image: Darren Naish.

A captive Corucia in a commercial collection. Image: Darren Naish.

Skinks are an enormous, globally distributed group of lizards. As of December 2019, there are around 1685 recognised species, accounting for about 25% of living lizard diversity (there are about 6780 lizard species in total), and – perhaps unsurprisingly – I’ve written about them quite a lot at TetZoo… though it’s now hard to appreciate this, since the articles concerned have variously been vandalised, curtailed or paywalled by the hosters of TetZoo ver 2 and ver 3. See links below for the wayback machine versions of these articles.

There’s a lot about skinks in the TetZoo archives, please see the links below. Thank Christ for wayback machine.

There’s a lot about skinks in the TetZoo archives, please see the links below. Thank Christ for wayback machine.

Among the most remarkable and striking of skinks is the large Solomon Islands skink or Monkey-tailed skink Corucia zebrata, a prehensile-tailed, mostly green, arboreal skink, and the only member of its genus (though read on). Not only is this amazing lizard green, arboreal and equipped with a powerful prehensile tail, it’s also a giant, especially big specimens reaching 72 cm in total length. This makes it the biggest known skink. It first became known to science in 1856 when indefatigable taxonomist John E. Gray tersely described specimens brought to London by John MacGillivray after his voyage aboard the HMS Herald, the type specimens coming specifically from San Christoval (today termed San Cristobal or Makira) in the Solomon Islands (Gray 1856).

The Solomon Islands. Image by OCHA (original here), CC BY 3.0.

The Solomon Islands. Image by OCHA (original here), CC BY 3.0.

The lizards appear widespread throughout the archipelago (Makira is one of the most southerly islands there) and are variable, differing in eye colour, size, and in the configuration and size of their scales. Some experts think that subspecies should be named to reflect this variation, and the smaller, paler-eyed northern form was named C. z. alfredschmidti in 1997 (Köhler 1997). Maverick Australian bad boy herpetologist Raymond Hoser has claimed the existence of several entirely new species of Corucia, one of which he named for his mother. If you want to know more about Mr Hoser (and why he’s a total joke) see the TetZoo article here.

A captive Corucia in a private collection. Note the dark irides which make this individual look different from some of the other animals shown here. Image: S. Hilgers.

A captive Corucia in a private collection. Note the dark irides which make this individual look different from some of the other animals shown here. Image: S. Hilgers.

So far, all published work on the phylogeography and variation within Corucia finds it and its divergences to be young; as in, younger than about 4 million years old (Hagen et al. 2012). Yet it must have diverged from its closest living relatives 20 million years ago or more (we can infer this because fossils of other members of the same skink group are this old or older), meaning that the vast bulk of its lineages’ history remains completely unknown, for now.

Gray described Corucia as a new member of the ‘fish-scaled’ skink group. This seems a bit odd today, because we don’t refer to any skink by this moniker (to my knowledge). He evidently regarded it as part of the Australasian skink group that includes Egernia, Tiliqua (the blue-tongues) and kin though. Today we think (on the basis of molecular phylogenetics) that this is correct, and that Corucia is a lygosomine skink (Skinner et al. 2011, Pyron et al. 2013).

Representatives of most (but not all) of the skink lineages currently regarded as ‘families’ by Hedges and colleagues. 1: Mabuya, of Mabuyidae. 2: Acontias, of Acontidae (I think it should really be Acontiidae). 3: Ristella, of Ristellidae. 4: Scinc…

Representatives of most (but not all) of the skink lineages currently regarded as ‘families’ by Hedges and colleagues. 1: Mabuya, of Mabuyidae. 2: Acontias, of Acontidae (I think it should really be Acontiidae). 3: Ristella, of Ristellidae. 4: Scincus, of Scincidae. 5: Lygosoma, of Lygosomidae. 6: Egernia, of Egerniidae. 7: Eugongylus, of Eugongylidae. These images are from my in-prep textbook, progress of which can be observed here. Images: Darren Naish.

Traditionally, all skinks are combined in the single family Scincidae. Most herpetologists argue that we should stick with this taxonomic system since there’s no dispute that Scincidae is a clade and thus no real need to shake things up. But some argue that putting all the species of this enormous, complex group into the same single ‘family’ obscures and under-emphasises its diversity and disparity and that it would be more realistic to split it into a whole bunch of families (nine in fact: Acontidae, Atechosauridae, Egerniidae, Eugongylidae, Lygosomidae, Mabuyidae, Ristellidae, Scincidae and Sphenomorphidae) (Hedges & Conn 2012, Hedges 2014). I’ve written about this situation before: see the articles below for more. If we follow this revised family-level classification, Corucia is part of Egerniidae.

Substantially simplified cladogram depicting lygosomine skink phylogeny, mostly based on Pyron et al. (2013). Images (top to bottom): Wolfgang Wuster, H. Zell, $Mathe94$, Benjamint444 (all CC BY-SA 3.0), Mark Stevens (CC BY 2.0), W. A. Djatmiko, S. …

Substantially simplified cladogram depicting lygosomine skink phylogeny, mostly based on Pyron et al. (2013). Images (top to bottom): Wolfgang Wuster, H. Zell, $Mathe94$, Benjamint444 (all CC BY-SA 3.0), Mark Stevens (CC BY 2.0), W. A. Djatmiko, S. Caut et al. (both CC BY-SA 3.0).

The name Corucia is derived from ‘coruscus’ (meaning shimmering, and referring to the shiny scales), while zebrata is a reference to the stripes present in the specimens Gray was familiar with. Given that Solomon Islanders know this lizard and eat it, there was and is surely indigenous knowledge of the species and probably lore about it, though I haven’t encountered such so far. It’s generic name shouldn’t be confused with that of the Cretaceous fossil lizard Carusia, a possible relative of the living xenosaurids.

Here in the UK, it’s currently not difficult to encounter Corucia in captivity. I should add that it does well if conditions are right: as a canopy-dwelling lizard it needs tall branches with suitable retreats, and some collections (most notably the Philadelphia Zoo) have been breeding Corucia for over 40 years now. They’re not especially active during peak visitor time at zoos, mostly because they’re crepuscular. They’re also exclusively herbivorous and are in fact the only skinks said to be committed to a plant diet. Leaves, shoots, flowers and fruit are all consumed, including those of toxic species. Their dung has a distinctive aroma and it’s apparently possible to locate trees inhabited by this species by smell alone: Harmon (2002) used this technique, making his study “the first documented use of olfactory cues to locate skinks in the wild” (p. 177).

Fine side-eye from this captive Corucia at Bristol Zoo, UK. Image: Darren Naish.

Fine side-eye from this captive Corucia at Bristol Zoo, UK. Image: Darren Naish.

Corucia is viviparous with a 6 to 8 month gestation, but the big deal about its viviparous strategy is that its babies are proportionally enormous, being about half the size of the mother. They can be over 30 cm long and weigh 175 g. Unsurprisingly, only a single baby is normally produced, though rare cases of twins and triplets are on record.

Corucia is also a social skink. In this, it’s far from unique, since egerniids of more than 20 species live together in family groups and even exhibit monogamy, kin recognition, colonial living and co-operation. Juvenile Corucia sometimes stay with their parental group for an extended period and mothers are reported to be highly protective of newborn juveniles (Wright 2007), which is what theory predicts given the substantial material investment involved in growing such a large baby. Also interesting is that not all the adults which form social groups in this species appear related (Wright 1996), and that Corucia groups are even known to allow orphaned juveniles to join their groups (read on…). Some juveniles do apparently leave their parental group to join others (Wright 2007).

Dark-eyed captive Corucia, and here’s proof that this arboreal lizard will - in captivity - drink from standing water (at least some arboreal lizards don’t do this, they rely only on water droplets on leaves). Image: S. Hilger.

Dark-eyed captive Corucia, and here’s proof that this arboreal lizard will - in captivity - drink from standing water (at least some arboreal lizards don’t do this, they rely only on water droplets on leaves). Image: S. Hilger.

Studies of wild-living Corucia on Ugi Island in the Solomon archipelago showed that individuals living less than 150 m apart were likely to be related, but also that individuals wandered for several kilometres (Hagen et al. 2013). Telemetry results obtained in an earlier study (Hagen 2011) indicate that this sort of dispersal is unusual, however, given that Corucia is mostly sedentary with home ranges being equivalent to the canopy of a single tree. Maybe this explains why groups are apparently happy to ‘adopt’ lone youngsters – they may well be related to the members of the group already. After all, we know that kin selection is at play elsewhere in social egerniids.

One of the latest papers discussing social behaviour in these skinks is also among the most shocking, since it reports the occurrence of a Corucia group living together in a deep tree hole, and one that was flooded at its bottom. Remarkably, some of the Corucia in the hole were fully submerged and located beneath the water surface at the time of discovery. To my supreme frustration, I can’t locate this publication right now, even though I recall downloading it (it was a short note in, perhaps, Salamandra or Journal of Herpetology). Let me know if you know the paper concerned. It was such a bizarre report that more information is needed. And I guarantee that it’s legit and that I didn’t dream it.

A captive Corucia at Bristol Zoo. Note the sharply curved claws and interesting nose in these lizards. Image: Darren Naish.

A captive Corucia at Bristol Zoo. Note the sharply curved claws and interesting nose in these lizards. Image: Darren Naish.

Finally, what does the future hold for this amazing lizard? Unsustainable destruction of forests on the Solomon Islands poses a problem, as does local hunting for the pot and collecting for the pet trade: between 1992 and 1995, 12000 animals were exported for this reason, mostly to the USA (Mann & Meek 2004). Consequently, Corucia is now being considered for inclusion on Appendix I of CITES, with captive breeding likely being crucial to its persistence.

Another captive Corucia. This image is useful and interesting because it shows the cross-sectional shape of the body: note that the side of the body is flat and that there’s an obvious change in angle between the side and dorsal surface. Image: TimV…

Another captive Corucia. This image is useful and interesting because it shows the cross-sectional shape of the body: note that the side of the body is flat and that there’s an obvious change in angle between the side and dorsal surface. Image: TimVickers (original here), public domain.

A giant, fully herbivorous, slow-breeding, social skink is such a special animal that we must make effort to ensure its survival into the future. And that’s where we must end.

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For previous TetZoo articles on skinks, see…

Refs - -

Gray, J. E. 1856. New genus of fish-scaled lizards (Scissosarae) from New Guinea. Annals and Magazine of Natural History (2) 18: 345-346.

Hagen, I. J. 2011. Home ranges in the trees: radiotelemetry of the Prehensile tailed skink, Corucia zebrata. Journal of Herpetology 45, 36-39.

Hagen, I. J., Donnellan, S. C. & Bull, C. M. 2012. Phylogeography of the prehensile-tailed skink Corucia zebrata on the Solomon Archipelago. Ecology and Evolution 2, 1220-1234.

Hagen, I. J., Herfindal, I., Donnellan, S. C. & Bull, C. M. 2013. Fine scale genetic structure in a population of the prehensile tailed skink, Corucia zebrata. Journal of Herpetology 47, 308-313.

Harmon, L. J. 2002. Some observations of the natural history of the Prehensile-tailed skink, Corucia zebrata, in the Solomon Islands. Herpetological Review 33, 177-179.

Hedges, S. B. 2014. The high-level classification of skinks (Reptilia, Squamata, Scincomorpha). Zootaxa 3765, 317-338.

Hedges, S. B . & Conn, C. E. 2012. A new skink fauna from Caribbean islands (Squamata, Mabuyidae, Mabuyinae). Zootaxa 3288, 1-244.

Köhler, G. 1997. Eine neue Unterart des Wickelschwanzskinkes Corucia zebrata von Bougainvillle, Papua-Neuguinea. Salamandra 33 (1), 61-68.

Mann, S. L. & Meek, R. 2004. Understanding the relationship between body temperatureand activity patterns in the giant Solomon Island skink, Corucia zebrata, as a contribution to the effectiveness of captive breeding programmes. Applied Herpetology 1, 287-298.

Pyron, R. A., Burbrink, F. T. & Wiens, J. J. 2013. A phylogeny and revised classification of Squamata, including 4161 species of lizards and snakes. BMC Evolutionary Biology 2013, 13:93.

Skinner, A., Hugall, A. F. & Hutchinson, M. N. 2011. Lygosomine phylogeny and the origins of Australian scincid lizards. Journal of Biogeography 38, 1044-1058.

Wright, K. 1996. The Solomon Islands skink. Reptile & Amphibian Magazine 3 (2), 10-19.

Wright, K. M. 2007. Captivating giants. Reptiles Magazine 15 (12), 54-68.