Limnaea stagnalis var. baltica Lindström, 1868: synonym of Lymnaea stagnalis (Linnaeus, 1758)
Distribution
The distribution of this species is holarctic, mainly the temperate zones of Northern America, Europe and Asia. The snail can be found in many ponds, lakes and very slow-moving rivers with a rich underwater vegetation. The northernmost populations exist in northern Norway, and in Central Europe, it inhabits even montane ecosystems at 1700 meters above sea level. In the Saprobiensystem used in Germany to judge the quality of freshwater biotopes, the species has a value of 1.9 and indicates a biotope with a water quality class II, the second-highest.[4]
Shell
For the terms used in this section, see gastropod shell. The shells vary from light brown to dark brown, and the height of an adult shell ranges from 45 to 60 millimeters. Rarely, snails with a 70 mm shell can be found. The width of an adult shell ranges from 20 to 30 mm.
The shell has 4.5 to 6 weakly convex whorls. The upper whorls are pointed, while the last whorl is suddenly inflated. Young great pond snails can be confused with those of the genus Physa, and rarely, in cases of irregularly grown shells, with Radix peregra—though adults of the latter species are a lot smaller, with shell heights of only 12 to 20 millimeters.
Lymnaea stagnalis is widely used for the study of learning, memory and neurobiology.[5]
Lymnaea stagnalis has a relatively simple central nervous system (CNS) consisting of a total of ~20,000 neurons, many of them individually identifiable, organized in a ring of interconnected ganglia. Most neurons of the Lymnaea stagnalis central nervous system are large in size (diameter: up to ~100 μm), thus allowing electrophysiological dissection of neuronal networks that has yielded profound insights in the working mechanisms of neuronal networks controlling relatively simple behaviors such as feeding, respiration, locomotion, and reproduction. Studies using the central nervous system of Lymnaea stagnalis as a model organism have also identified novel cellular and molecular mechanisms in neuronal regeneration, synapse formation, synaptic plasticity, learning and memory formation, the neurobiology of development and aging, the modulatory role of neuropeptides, and adaptive responses to hypoxic stress.[5]
Life cycle
Lymnaea stagnalis is a simultaneously hermaphroditic species and can mate in the male and female role, but within one copulation only one sexual role is performed at a time.[7]Lymnaea stagnalis perform more inseminations in larger groups and prefer to inseminate novel over familiar partners. Such higher motivation to copulate when a new partner is encountered is known as the Coolidge effect and has been demonstrated in hermaphrodites firstly in 2007.[7]
Lymnaea stagnalis snails can be easily be kept in a freshwater aquarium at room temperature, and fed with various sorts of vegetables, salad, cabbage and dandelion leaves. Fish food will also be eaten, as well as aquarium pests like algae, the Hydra viridissima polyp, and the eggs of other water snails.
Due to the development of toxic nitrates, leftover food must be removed in time, and the water exchanged often. Using a water conditioner is also recommended. Depending on water hardness, a piece of cuttlebone must be offered to cover the snails' calcium needs.
References
This article incorporates CC-BY-2.0 text from references[5][7] and CC-BY-2.5 text from the reference[6]
^Linnaeus C. (1758) Systema Naturae per regna tria naturae, secundum classes, ordines, genera, species, cum characteribus, differentiis, synonymis, locis. 10th edition. Vermes. Testacea: 700–781. Holmiae. (Salvius).
^Strictly speaking, the Saprobiensystem looks at the ability of a biotope to self-regulate its organic matter content under aerobic conditions.
^ abcFeng Z-P., Zhang Z., Kesteren R. E. van, Straub V. A., Nierop P. van, Jin K., Nejatbakhsh N., Goldberg J. I., Spencer G. E., Yeoman M. S., Wildering W., Coorssen J. R., Croll R. P., Buck L. T., Syed N. I. & Smit A. B. (23 September 2009) "Transcriptome analysis of the central nervous system of the mollusc Lymnaea stagnalis". BMC Genomics10: 451. doi:10.1186/1471-2164-10-451
^ abKoene J. M., Sloot W., Montagne-Wajer K., Cummins S. F., Degnan B. M., Smith J. S., Nagle G. T. & Maat A. ter (2010). "Male Accessory Gland Protein Reduces Egg Laying in a Simultaneous Hermaphrodite". PLoS ONE 5(4): e10117. doi:10.1371/journal.pone.0010117.
^Kudlai O. S. (2009). "The discovery of the intermediate host for the trematode Moliniella anceps (Trematoda, Echinostomatidae) in Ukraine". Vestnik zoologii43(4): e-11–e-13. doi:10.2478/v10058-009-0014-x.
^Leicht K. & Seppälä O. (2014). "Infection success of Echinoparyphium aconiatum (Trematoda) in its snail host under high temperature: role of host resistance". Parasites & Vectors7:192. doi:10.1186/1756-3305-7-192.
^ abcdefSoldanova M., Selbach C., Sures B., Kostadinova A. & Perez-del-Olmo A. (2010). "Larval trematode communities in Radix auricularia and Lymnaea stagnalis in a reservoir system of the Ruhr River". Parasites & Vectors 2010, 3: 56. doi:10.1186/1756-3305-3-56.
^Skorping A. (1985). "Lymnea stagnalis as experimental intermediate host for Elaphostrongylus rangiferi". Zeitschrift für Parasitenkunde71: 265–270.