Rheobatrachus silus

Rheobatrachus silus, commonly called southern gastric-brooding frog, is an extinct species of gastric-brooding frog native to Australia.

Distribution
The southern gastric-brooding frog was discovered in 1972 and described in 1973, though there is one publication suggesting that the species was discovered in 1914 (from the Blackall Range). Rheobatrachus silus was restricted to the Blackall Range and Conondale Ranges in southeast Queensland, north of Brisbane, between elevations of 350 and 800 m above sea level. The areas of rainforest, wet sclerophyll forest and riverine gallery open forest that it inhabited were limited to less than 1400 km2. They were recorded in streams in the catchments of the Mary, Stanley and Mooloolah Rivers.

Description
The southern gastric-brooding frog was a medium-sized species of dull colouration, with large protruding eyes positioned close together and a short, blunt snout. Its skin was moist and coated with mucus. The fingers were long, slender, pointed and unwebbed and the toes were fully webbed. The arms and legs were large in comparison to the body. The southern gastric-brooding frog was a dull grey to slate coloured frog that had small patches, both darker and lighter than the background colouration, scattered over dorsal surface (back). The ventral surface was white or cream, occasionally with yellow blotches. The arms and legs had darker brown barring above and were yellow underneath. There was a dark stripe that ran from the eye to the base of the forelimb. The ventral surface (belly) was white with large patches of cream or pale yellow. The toes and fingers were light brown with pale brown flecking. The end of each digit had a small disc and the iris was dark brown. The skin was finely granular and the tympanum was hidden. In both Rheobatrachus species, the females were larger than the males. The male Southern Gastric Brooding Frog was 30 to 44 mm in length and the female 41 to 54 mm in length.

Ecology and behaviour
The southern gastric-brooding frog lived in areas of rainforest, wet sclerophyll forest and riverine gallery open forest. They were a predominately aquatic species closely associated with watercourses and adjacent rock pools and soaks. Streams that the southern gastric-brooding frog were found in were mostly permanent and only ceased to flow during years of very low rainfall. Sites where southern gastric-brooding frogs were found usually consisted of closed forests with emergent eucalypts, however there was sites where open forest and grassy ground cover were the predominant vegetation. There is no record for this species occurring in cleared riparian habitat. Searches during spring and summer showed that the favoured diurnal habitat was at the edge of rock pools, either amongst leaf litter, under or between stones or in rock crevices. They were also found under rocks in shallow water. Winter surveys of sites where southern gastric-brooding frogs were common only recovered two specimens, and it is assumed that they hibernated during the colder months. Adult males preferred deeper pools than the juveniles and females which tended to inhabit shallower, newly created (after rain) pools that contained stones and/or leaf litter. Individuals only left themselves fully exposed while sitting on rocks during light rain.

The frog's diet was observed to include insects from both land and water.

The call of the southern gastric-brooding frog has been described as an "eeeehm...eeeehm" with an upward inflection. It lasts for around 0.5 s and was repeated every 6–7 seconds.

Southern gastric-brooding frogs have been observed feeding on insects from the land and water. In aquarium situations Lepidoptera, Diptera and Neuroptera were eaten.

Being a largely aquatic species the southern gastric-brooding frog was never recorded more than 4 m from water. Studies by Glen Ingram showed that the movements of this species were very restricted. Of ten juvenile frogs, only two moved more than 3 metres between observations. Ingram also recorded the distance moved along a stream by seven adult frogs between seasons (periods of increased activity, usually during summer). Four females moved between 1.8 - 46 m and three males covered 0.9 - 53 m. Only three individuals moved more than 5.5 m (46 m, 46 m and 53 m). It appeared that throughout the breeding season adult frogs would remain in the same pools or cluster of pools, only moving out during periods of flooding or increased flow.

Population decline and extinction
In 1976, the Southern gastric-brooding frog's population was estimated at 78 individuals in the Booloumba Creek and Conondale Range regions. The Southern gastric-brooding frog suffered from population decline after the winter of 1979. The last recording of the frog in the wild was 1981. In 1983, the last known captive specimen died. Intensive searches for the frog were undertaken in 1995, 1996, and 1997 in its previously known habitats.

The Southern gastric-brooding frog was declared extinct in 2000 as per the EPBC Act. Due to the brief period between its discovery and its extinction, the causes remain unclear. However, land use change, invasive species, and chytridiomycosis have been listed as possible factors.

De-extinction attempt
Scientists are making progress in their efforts to bring the gastric-brooding frog species back to life using somatic-cell nuclear transfer (SCNT), a method of cloning.

In March 2013, Australian scientists successfully created a living embryo from non-living preserved genetic material. These scientists from the University of Newcastle Australia led by Prof Michael Mahony, who was the scientist who first discovered the northern gastric-brooding frog, Simon Clulow and Prof Mike Archer from the University of New South Wales hope to continue using somatic-cell nuclear transfer methods to produce an embryo that can survive to the tadpole stage. "We do expect to get this guy hopping again," says UNSW researcher Mike Archer.

The scientists from the University of Newcastle have also reported successful freezing and thawing (cryopreservation) of totipotent amphibian embryonic cells, which along with sperm cryopreservation provides the essential "proof of concept" for the use of cryostorage as a genome bank for threatened amphibians and also other animals.