|Drawing of the shell of Sphincterochila boissieri.|
informal group Sigmurethra
Sphincterochila boissieri is the type species of the genus Sphincterochila. The type species was subsequently designated by Henry Augustus Pilsbry in 1895. It is named after botanist Pierre Edmond Boissier.
The shell of Sphincterochila boissieri is covered perforate, thick, irregularly striated, somewhat effulgent, cretaceous and colored white. It has 5 slightly convex whorls. The last whorl is deflected anteriorly. The aperture has a thick lip, projecting internally above in two thick, subconfluent tubercles.
The average width of the shell is 25 mm.
Anatomy and physiology
The average body mass of Sphincterochila boissieri is around 4.3 g. Such mass is divided evenly between the shell and the animals soft parts. Schmidt-Nielsen et al., in 1971, found that 56% of the animals body mass was contained in its shell. About 80 to 90% of the mass of the soft body parts is composed of water (according to the Yom-Tov 1970). In average, soft body parts contain 81% of water (nearly 1400 mg of water), 11% of proteins, 4% of ash, and little other organic matter. Sphincterochila boissieri has no energy reserves and the amount of lipids it contains is a fraction of 1%, which is considered to be extremely low.
Yom-Tov measured the maximum demographic density for Sphincterochila boissieri, encountering a value of 0.2-0.3 specimens/m² in the area of the Negev desert he investigated in 1970. The snail Xerocrassa seetzeni was found to be more abundant there. On the other hand, in the Northern Negev area investigated by Steinberger et al. In 1981 Sphincterochila boissieri was the most abundant snail.
Adaptations for arid conditions
This species presents adaptations to arid conditions which significantly improve its desiccation tolerance. Some of those adaptations include a thick shell with a relatively reduced aperture (see also Machin 1967), a thick epiphragm, and slow body surface heat conduction. About 90% of its shell surface reflects the visible portion of the solar spectrum, and much over 90% of the solar spectrum itself. Sphincterochila boissieri also produces a new epiphragm after every period of activity (see also Yom-Tov 1971).
These snails dig themselves into the soil to depths from 1 to 5 cm while they aestivate during summer in the Negev Desert. In the vicinity of the Dead Sea, they usually either burrow to depths of up to 10 cm, or aestivate hidden under stones.
All dormant snails of this species can resist ambient temperatures up to 50 °C, but temperatures of 55 °C and above are usually lethal. The soft parts of the animal's body shelter inside the second and the third whorl of its shell, where the temperature can reach up to 50.3 °C. Temperatures of up to 56.2 °C were measured and are known to occur inside the shell's body whorl, which is mostly filled with air during aestivation.
Dormant snails experience water loss of 0.5 mg per day per snail in summer, with a very low oxygen consumption rate. For these reasons, dormant Sphincterochila boissieri can survive severe droughts for several years.
Sphincterochila boissieri is active for a few days only after rainfall during the winter season, from November to March. At this time of the year they feed, mate, and lay eggs. Thus these snails are active for only 5-7% of the year (nearly 18 to 26 days), and aestivate during all the rest of the time.
Dormant snails are known to have survived in museum collections for up to 6 years. Schmidt-Nielsen et al. in 1971 estimated their life span according to their oxygen consumption as being nearly 8 years.
The known predators of Sphincterochila boissieri are rodents, namely the Cairo Spiny Mouse (Acomys cahirinus), Wagner's Gerbil (Dipodillus dasyurus) and the Asian Garden Dormouse (Eliomys melanurus).
This article incorporates public domain text from the reference.
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