OSMOTIC ADJUSTMENT IN AN ESTUARINE POPULATION OF<i>UROSALPINX CINEREA</i>(SAY, 1822) (MURICIDAE, GASTROPODA)

Turgeon, Kenneth W.

doi:10.2307/1540509

Cited by 6 publications

(11 citation statements)

References 24 publications

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“…Only three other studies are available, (exclusively assessing molluscs) that measured inorganic as well as organic compounds after longterm low-salinity acclimation. Similar to our results, these studies found significant effects of salinity on both osmolyte pools and a larger inorganic pool size (Potts, 1958;Turgeon, 1973;Silva, 1992).…”

Section: Cellular Osmoregulationsupporting

confidence: 90%

Capacity for Cellular Osmoregulation Defines Critical Salinity of Marine Invertebrates at Low Salinity

Podbielski

Hiebenthal²,

Hajati³

et al. 2022

Front. Mar. Sci.

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Low-salinity stress can severely affect the fitness of marine organisms. As desalination has been predicted for many coastal areas with ongoing climate change, it is crucial to gain more insight in mechanisms that constrain salinity acclimation ability. Low-salinity induced depletion of the organic osmolyte pool has been suggested to set a critical boundary in osmoconforming marine invertebrates. Whether inorganic ions also play a persistent role during low-salinity acclimation processes is currently inconclusive. We investigated the salinity tolerance of six marine invertebrate species following a four-week acclimation period around their low-salinity tolerance threshold. To obtain complete osmolyte budgets, we quantified organic and inorganic osmolytes and determined fitness proxies. Our experiments corroborated the importance of the organic osmolyte pool during low-salinity acclimation. Methylamines constituted a large portion of the organic osmolyte pool in molluscs, whereas echinoderms exclusively utilized free amino acids. Inorganic osmolytes were involved in long-term cellular osmoregulation in most species, thus are not just modulated with acute salinity stress. The organic osmolyte pool was not depleted at low salinities, whilst fitness was severely impacted. Instead, organic and inorganic osmolytes often stabilized at low-salinity. These findings suggest that low-salinity acclimation capacity cannot be simply predicted from organic osmolyte pool size. Rather, multiple parameters (i.e. osmolyte pools, net growth, water content and survival) are necessary to establish critical salinity ranges. However, a quantitative knowledge of cellular osmolyte systems is key to understand the evolution of euryhalinity and to characterize targets of selection during rapid adaptation to ongoing desalination.

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Section: Cellular Osmoregulationsupporting

confidence: 90%

Capacity for Cellular Osmoregulation Defines Critical Salinity of Marine Invertebrates at Low Salinity

Podbielski

Hiebenthal²,

Hajati³

et al. 2022

Front. Mar. Sci.

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“…Certainly the recent literature supports this generalization. Several authors have investigated the effects of salinity changes on the osmotic and ionic concentrations of the extracellular fluid and all of these studies have indicated that the snails were essentially isosmotic/isionic over the tolerated salinity ranges (Todd, 1964a, b;Turgeon, 1976;Avens and Sleigh, 1965). There are, however, exceptions.…”

Section: Discussionmentioning

confidence: 99%

“…Several authors have demonstrated a decrease in the FAA pool of prosobranch gastropods following transfer to dilute media (Staaland, 1970;Turgeon, 1976;Negus, 1968;Ivanovici et al 1981;Bedford, 1971a) whereas other species have shown no such decrease (Emerson, 1969;Peterson and Duerr, 1969). The total concentration of the FAA pool in A. crenata is comparable to other marine and estuarine molluscs studied (Simpson et al, 1959;Peterson and Duerr, 1969;Turgeon, 1976); however, previous studies have shown that the total concentration of the FAA pool is attributable to only a few individual FAA (Gly, Ala, Pro, Glu, Tau, Asp, Glutamine) with Gly and Ala sometimes constituting up to 50% of the total concentration. We have demonstrated here that A. crenata utilizes the FAA pool in osmotic regulation when exposed to dilute media (Tables I, II).…”

Section: Discussionmentioning

confidence: 99%

Osmotic Balance in a Marine Pulmonate,Amphibola crenata

Shumway

Freeman

1984

Marine Behaviour and Physiology

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The pulmonate mud-snail Amphibola crenata is an osmoconformer in 25%-125% sea water, its haemolymph being slightly hyperosmotic and hyperionic to the medium. It maintains its haemolymph markedly hyperosmotic in media below 25% sea water and in freshwater, in which it survives for a week or longer. On exposure to dilute or concentrated media, water which enters or leaves the tissues preferentially enters or leaves the cells. Regulation of cell volume towards initial values is accomplished within 5 days. Measurements of changes in cell volume, and of distribution of tissue water between the intracellular and extracellular compartments, in snails moved from 100% sea water into dilute or concentrated media, and in snails moved back to 100% sea water, indicate that mechanisms of cell volume regulation are minimal in ca 60-65% sea water. Changes in the concentration of tissue free amino acids are in accord with current theories of mechanisms of isosmotic intracellular regulation. The results are discussed in the light of the taxonomic, evolutionary and ecological status of Amphibola as a shore-living, primitive, marine representative of a predominantly terrestrial and freshwater group of gastropod molluscs.

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“…In Tegula funebralis, ninhydrin-positive substances were found in greater concentrations in the whole body of animals living in sea water than in 50% sea water (Peterson & Duerr, 1969); but the snails in 50% sea water may well have been showing sublethal effects, since they had a high mortality rate. In Urosalpinx cinerea, taurine concentrations in the whole body decreased by 50% when the snails were transferred from 100% to 50% sea water (Turgeon, 1976). In Buccinum undatum, ninhydrin-positive substances were halved in 50% sea water compared to 100% sea water (Staaland, 1970).…”

Section: Terrestrial Prosobranchsmentioning

confidence: 96%

“…In Urosalpinx, the water content of the whole animal increased gradually from 40 %o to 10 %o (Turgeon, 1976). In Urosalpinx, the water content of the whole animal increased gradually from 40 %o to 10 %o (Turgeon, 1976).…”

Section: Terrestrial Prosobranchsmentioning

confidence: 97%

Osmoregulation and Excretion in Prosobranch Gastropods Part I: Physiology and Biochemistry

Little

1981

Journal of Molluscan Studies

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INTRODUCTIONThe mechanisms of excretion in molluscs were reviewed by Potts (1967), and those specific to gastropods by Potts (1975), but reviews of osmoregulation in invertebrates have usually taken a broad view and dealt with a number of phyla. This review, which is presented in two parts, attempts to summarize current knowledge concerning both excretion and osmoregulation in prosobranch gastropods.Prosobranch gastropods have colonized a very wide range of habitats, from the sea and brackish waters to fresh water and parts of the land. Their degree of tolerance of changes in external conditions is therefore immensely varied. Some marine species are closely confined to normal sea water, while estuarine species such as Assiminea grayana Fleming can tolerate a range from fresh water to twice the concentration of sea water (Seelemann, 1968b;Little & Andrews, 1977). Freshwater species also show great diversity: Valvata piscinalis (Miiller) and V. cristata Miiller are found in waters with as little calcium as 0.13 mM 1~', whereas others such as V. macrostoma Morch require at least 0.5 mM 1~' (Boycott, 1936). On land, most prosobranchs are restricted to humid, calcium-rich environments, but although none lives in deserts as do some pulmonates, many tropical species of Pomatiasidae are found on dry limestone cliffs.This variation in tolerance must also be considered with reference to the diversity of structural organization. Scattered information is available for more than 25 different families, including members of all the prosobranch orders, so that it is not surprising to find quite a degree of variation. To avoid confusion, the species and families referred to are set out in Table 1.

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OSMOTIC ADJUSTMENT IN AN ESTUARINE POPULATION OFUROSALPINX CINEREA(SAY, 1822) (MURICIDAE, GASTROPODA)

Cited by 6 publications

References 24 publications

Capacity for Cellular Osmoregulation Defines Critical Salinity of Marine Invertebrates at Low Salinity

Capacity for Cellular Osmoregulation Defines Critical Salinity of Marine Invertebrates at Low Salinity

Osmotic Balance in a Marine Pulmonate,Amphibola crenata

Osmoregulation and Excretion in Prosobranch Gastropods Part I: Physiology and Biochemistry

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