Heart rate variation patterns in some representatives of Bivalvia

The pattern of heart rate variation was studied in bivalves sublittoral (aquaculture) and littoral mussels Mytilus edulis L. and Hiatella arctica L. in a long-term experiment at constant salinity (25‰) and temperature (10°C). Periodic changes in heart rate were observed in both littoral and sublittoral mussels. Heart activity could regularly decrease up to temporary cardiac arrest. Changes in H. arctica heart rate were much less pronounced compared to mussels and no cardiac arrest was observed.     

The effect of salinity change on the heart rate of Mytilus edulis specimens from different ecological zones

The heart rate of specimens of Mytilus edulis (L.) both from the sublittoral and littoral zones exposed to normal and altered salinity was investigated in a long-term experiment. The heart rate was monitored by a non-invasive method for nine days. The heart rate of sublittoral mussels was higher than that of littoral ones. This suggests a higher level of metabolic activity in sublittoral mussels. When exposed to moderate hyposalinity (15 g l⁻¹) M. edulis from both zones showed a significant decrease in the heart rate with respect to the control salinity (25 g l⁻¹), but sublittoral mussels had a more prominent bradycardia. The heart beat quickly accelerated in all organisms when they were returned to the control salinity medium. Throughout the experiment, heart contractions halted with distinct periodicity in all mussels.     

Modulating role of lipids and their fatty acids in adaptation of the White Sea mussels <Emphasis Type="Italic">Mytilus edulis</Emphasis> L. to environmental salinity change

Role of lipids and fatty acids (FA) in littoral and sublittoral White Sea mussels Mytilus edulis L. was studied at various stages of reproductive cycle in the phenotypic adaptation (acclimation) to changes of the sea water salinity. The obtained data indicate differences in the mussel lipid and fatty acid spectra, which are connected both with their location (littoral or sublittoral) and with the spawning period stage (3b—release of gametes or 3c—resorption of residual sex products). Lipids and FA of both mussel groups respond to the salinity changes to the greater degree at the 3b than at the 3c stage. In the littoral mussels at the 3b and 3c stages there were revealed differently directed changes in the content of membrane lipid—cholesterol—and in the cholesterol: phospholipids ratio. In the sublittoral mussels that are less adapted to extreme action of abiotic factors, more significant changes were found in the lipid and FA compositions.     

Modulatory role of lipids and their fatty acids in adaptation of the White Sea mussels Mytilus edulis L. to environmental salinity changes

Role of lipids and fatty acids (FA) in littorial and sublittorial White Sea mussels Mytilus edulis L. was studied at various stages of reproductive in the phenotypic adaptation (acclimation) to changes of the sea water salinity. The obtained data indicate differences in the mussel lipid and fatty acid spectra, which are connected both with their location (littoral and sublittoral) and with the spawning period stage (3b--release of gametes and 3c--resorption of residual sex products). Lipids and FA of both mussel groups respond to the salinity changes to the greater degree at the 3b than at the 3c stage. In the littorial mussels at the stages 3b and 3c there were revealed differently directed changes in the content of membrane lipid--cholesterol--and in the cholesterol : phospholipids ratio. In the sublittorial mussels that are less adapted to extreme action of abiotic factors, more significant changes were found in the lipid and FA compositions.     

Effects of seawater acidification and salinity alterations on metabolic,osmoregulation and oxidative stress markers in Mytilus galloprovincialis

The impacts of seawater acidification and salinity shifts on metabolism, energy reserves, and oxidative status of mussels have been largely neglected. With the aim to increase the current knowledge for the mussel Mytilus galloprovincialis a 28-day chronic test was conducted during which mussels were exposed to two pH (7.8 and 7.3; both at control salinity 28) and three salinity (14, 28 and 35, at control pH, 7.8) levels. After exposure to different conditions, mussels electron transport system activity, energy reserves (protein and glycogen content) carbonic anhydrase activity, antioxidant defences and cellular damage were measured. Results obtained showed that mussels exposed to seawater acidification presented decreased metabolic capacity that may have induced lower energy expenditure (observed in higher glycogen, protein and lipids content at this condition). Low pH condition induced the increase of carbonic anhydrase activity that was related to acid-base balance, while no significant activation of antioxidant defence mechanisms was observed resulting in higher LPO. Regarding the impacts of salinity, the present study showed that at the highest salinity (35) mussels presented lower metabolic activity (also related to lower energetic expenditure) and an opposite response was observed at salinity 14. Carbonic anhydrase slightly increased at stressful salinity conditions, a mechanism of homeostasis maintenance. Lower metabolic activity at the highest salinity, probably related to valves closure, helped to mitigate the increase of LPO in this condition. At low salinity (14), despite an increase of antioxidant enzymes activity, LPO increased, probably as a result of ROS overproduction from higher electron transport system activity. The present findings demonstrated that Mytilus galloprovincialis oxidative status and metabolic capacity were negatively affected by low pH and salinity changes, with alterations that may lead to physiological impairments namely on mussels reproductive output, growth performance and resistance to disease, with ecological and economic implications.Indicators: Physiological and biochemical changes in Mytilus galloprovincialis in response to low pH and salinity changes     

Effect of salinity change on cardiac activity in Hiatella arctica and Modiolus modiolus, in the White Sea

A great majority of salinity studies have dealt with intertidal species. Little is known about the way subtidal animals respond to salinity fluctuations. Even less details are available on invertebrates from the White Sea, which salinity is ca. 25. The heart rate of two subtidal Bivalvia—Hiatella arctica and Modiolus modiolus—exposed to different salinities was recorded. Changes in cardiac activity were monitored for 9 days of the animals’ acclimation to salinities of 15, 20, 30 and 35, and for 4 days of reacclimation (return to the initial salinity of 25). The initial response to salinity change was a significant heart rate reduction. On the other hand, cardiac activity in M. modiolus intensified at salinities of 30 and 35. Reacclimation induced different HR responses: from a decrease to a rise, depending on the species and the salinity applied in the experiment. The differences in responses to salinity are discussed with respect to the morphological and ecological characteristics of the species.     

Responses to low salinity by the sea star Pisaster ochraceus from high‐ and low‐salinity populations

Abstract. In many coastal environments, variation in salinity and organismal responses to that variation are important determinants of the distribution and abundance of species. This study examined the effects of acute salinity changes on sea stars (Pisaster ochraceus) collected from a high‐salinity site (Bamfield, BC) and a low‐salinity site (Vancouver, BC). Sea stars from both sites were exposed to salinities ranging 15–30 psu. Following a 24‐h exposure, the osmolality, sodium concentrations, and chloride concentrations in the perivisceral fluid all varied directly with salinity and were very close to the treatment salinities in both the Bamfield and Vancouver sea stars. The righting response (measured as an activity coefficient) was salinity dependent, with the lowest activity levels at a salinity of 15 psu. Activity coefficients did not vary between the two source populations. Feeding rates on mussels were strongly salinity dependent, but the salinity pattern was population specific. Bamfield sea stars fed the most at 30 psu, whereas Vancouver sea stars fed the most at 20 psu. High post‐experimental mortalities were observed in Bamfield sea stars that had been exposed to a salinity of 15 psu; no such mortality was observed in Vancouver animals. This study provides evidence that the sea stars from the lower salinity environment had been able to acclimatize or adapt to low‐salinity conditions. However, the results also suggest that there are limits to this tolerance, and that future changes in salinity may have important consequences for marine communities via alteration of keystone predation.     

Effect of the Razdol’naya River on structure of the free-living nematode community of the Amursky Bay,Sea of Japan

The effect of the Razdol’naya River on the littoral and sublittoral nematode community was studied in the innermost part of the Amursky Bay. Thanks to the seasonal abundance of juveniles of macrobenthic animals, pseudomacrobenthic species prevailed in the meiobenthos littoral community. Juvenile amphipods dominated (39.5%), the percentage of nematodes was 18.4% (45 species). The nematodes dominated in the meiobenthos community (65.7%, 71 species) at the sublittoral zone. The similarity of the species structure of littoral and sublittoral nematodes reached 36.5%. Low population density (2.6±1.7 thousand ind/m²) and poor species diversity of nematodes (7 species), the dominating form being Oncholaimium paraolium, were recorded at the littoral zone, which was subjected to direct riverine influence (1‰salinity). The correlation analysis revealed no relationship between salinity and population density of nematodes at the littoral zone. At the sublittoral zone (at stations of salinity less than 2.85‰) the parameters of population density (73.9±32.3 thousand ind/m²) and species diversity (12 species) of nematodes were the lowest, Parodontophora timmica dominated. A poor expressed dependence between the density of nematode populations and salinity was revealed. The correlation between the average size of ground particles and population density of nematodes was recorded. The greatest similarity of the species structure of littoral and sublittoral nematodes (26.67%) was recorded on gravel-sand bottoms.     

Effect of temperature and salinity on acetylcholinesterase activity, a common pollution biomarker, in Mytilus sp. from the south-western Baltic Sea

Acetylcholinesterase (AChE) activity is a well established biomarker to monitor environmental pollution caused by neurotoxic compounds, such as organophosphorus and carbamate pesticides. The presence of these compounds results in a measurable inhibition of the enzyme. This has been shown for different marine species including blue mussels. Besides pollution, environmental variables may also have a direct or indirect effect on AChE activity, particularly in estuarine and brackish water environments. To assess the impact of abiotic factors on the AChE activity the seasonal course of gill AChE activity was followed in relation to temperature and salinity in Mytilus sp. collected from the south-western Baltic Sea. In addition, the effect of salinity on AChE activity was investigated in an experimental study. The AChE activity showed significant seasonal differences with maximum activities during the summer period and minimum activities in winter. These changes correlate significantly (p<0.001) and positively with water temperature. The experimental exposure of Mytilus sp. to different salinities (5, 7, 16 or 20 psu) resulted in changes in the gill AChE activity. Empirical orthogonal function (EOF) analysis revealed that AChE activity was significantly and negatively correlated with salinity (p<0.01). These results clearly demonstrate the need to consider the potential influence of temperature and salinity on AChE activity when applying this biomarker to monitor exposure to and effect of neurotoxic substances in estuarine and brackish water blue mussels.     

Investigations on the autecology of Eugomontia sacculata Kornm., A shell-boring alga

Laboratory culture studies on the salinity and light tolerance of Eugomontia sacculata Kornm, from different habitats suggest that the species has at least two physiological variants adapted to particular habitat conditions. Plants taken from a shallow estuary survived in culture under higher light intensities than plants collected from the sublittoral region, while sublittoral plants were unable to tolerate the reduced salinity in which the estuarine plants were able to live. The host shell may provide protection from unfavourable changes in the external conditions and will also modify some environmental factors such as light intensity and its spectral composition. The possible rôle of light in the morphogenesis of shell-boring algae is discussed.     

The effect of environmental salinity on the level of heat shock proteins in gill epithelium of Mytilus edilis L. mussel

The composition and the level of heat shock proteins in the gill epithelium cells of mussels Mytilus edulis L. from the White Sea under different levels of environmental salinity were studied by the method of immunoblotting. In mussels maintained under normal salinity (26%), constitutive Hsp70 and protein of about 40 kDa were revealed. After long-term (11?C14 days) acclimation to 14 and 35?? of the level Hsp70 in gill epithelium cells increased. Hsp70 induction was also observed in cells of isolated gills after salinity shock at 14% for 3 and 24 h.     

Changes in the immune response and metabolic fingerprint of the mussel, Mytilus edulis (Linnaeus) in response to lowered salinity and physical stress

Mussels, such as Mytilus edulis, are common keystone species on open coasts and in estuaries and are frequently used in environmental monitoring programmes. Mussels experience a wide range of environmental conditions at these locations, including rapid changes in salinity and physical disturbance (both natural and from aquaculture practices).This paper addressed the hypothesis that reduced salinity will lower mussel blood immune function and influence mussel blood metabolic responses, and that this will in turn increase the susceptibility of mussels to other stresses such as physical disturbance. To test these hypotheses, experiments were conducted in controlled laboratory tank conditions and mussel blood was analysed using a combination of metabolic fingerprinting with FT-IR and immunological assay techniques.Reducing seawater salinity to half that of normal caused a significant reduction in several measures of immune function, including the concentration of haemocytes, percentage of eosinophilic haemocytes and phagocytosis. Mechanical shaking of mussels for 10 min caused a reduction in the level of respiratory burst activity. However, there was no evidence of additive or interactive effects of lowered salinity with shaking on the immune response. Analysis of mussel blood metabolic fingerprints revealed differences in response to half salinity (vs. full salinity) but there were no detectable effects of shaking. Increasing frequency and magnitude of flood events at coastal sites due to climate change could lead to longer, and more frequent, periods of reduced salinity. The potential impact on the immune function of this keystone species within or near estuaries could have knock-on effects on the wider ecosystem including altered nutrient cycling, changes in biodiversity and aquaculture production.     

Effects of temperature,salinity and agitation on byssus thread formation of zebra musselDreissena polymorpha

Byssus thread production ofD. polymorpha under different conditions of temperature, salinity and agitation were studied in the laboratory. The acclimation to salinity and temperature greatly affects the byssus production ofD. polymorpha. Byssus production of mussels was significantly reduced when temperature increased beyond 20°C and decreased below 10°C. Mussels with cut threads (for counting), produced a substantially increased number of threads. However, mussels with uncut byssus threads were comparatively more mobile. Byssus production of mussels did not vary significantly at salinities up to 3. Beyond this salinity byssus production was reduced significantly. Mussels increased their byssus production with increasing frequency of agitation.     

Physiological history may mask the inherent inducible desiccation tolerance strategy of the desert moss Crossidium crassinerve

Shoots of bryophytes collected in the desiccated state from the field are likely to be hardened to desiccation tolerance (DT) to varying degrees. To account for this, most studies on DT include a relatively short deacclimation period. However, no study has experimentally determined the appropriate deacclimation time for any bryophyte species. Our purposes are to (i) determine if ‘field effects’ are biologically relevant to DT studies and how long a deacclimation period is required to remove them; and (ii) utilise field versus cultured shoot responses within the context of a deacclimation period to elucidate the ecological strategy of DT. Our hypothesis (based on an extensive literature on DT) is that a deacclimation period from 24 to 72 h should be sufficient to eliminate historical stress effects on the physiology of the shoots and allow an accurate determination of the inherent ecological DT strategy (constitutive or inducible). We determined, however, using chlorophyll fluorescence and visual estimates of shoot damage, that field‐collected shoots of the desert moss Crossidium crassinerve required an experimental deacclimation period of >7 days before field effects were removed, and revealed an ecological DT strategy of inducible DT. If the deacclimation period was <6 days, the shoot response conformed to an ecological strategy of constitutive protection. Thus the presence of field effects can obscure the ecological strategy of desiccation tolerance exhibited by the species, and this translates into a need to re‐evaluate previous mechanistic and ecological studies of desiccation tolerance in plants.     

Some Observations on the Influence of Salinity on Photosynthetic Activity and Chloride Ion Loss in Several Seaweeds

The photosynthetic rates of Enteromorpha intestinalis, Fucus vesiculosus and Laminaria saccharina from the Baltic Sea were measured in different salinity range of Medium A (with NaHCO₃) and Medium B (without NaHCO₃). Photosynthetic activity in Medium A showed higher values than those in Medium B. The materials pretreated for one day showed a higher O₂ output than those untreated at almost every salinity range. In a chloride loss experiment the pretreated thalli of Porphyra umbilicalis, Fucus vesiculosus and Laminaria digitata were placed for a three minute period in distilled water. The excreted chloride ion content showed a higher value in sublittoral species after hypotonic and hypertonic treatment than in intertidal species.     

GROWTH AND MORTALITY OF THE MUSSELS CHOROMYTILUS MERIDIONALIS (KRAUSS) AND AULACOMYA ATER(MOLINA) AS INDICATORS OF BIOTIC CONDITIONS

Two mussels, Choromytilus meridionalis (Krauss) and Aulacomyaater, (Molina) were used as indicators of biotic factors thatapparently result in radically different sublittoral communitiesat two closely situated islands on the South African west coast.Specimens of both species were attached to submerged plates,which were either unprotected or protected from predation bycages. C. meridionalis grew faster and tolerated silting andsmothering better than A. ater. At Malgas Island adults of C.meridionalis are completely absent and those of A. ater scarcedue to intense predation by rock-lobsters. When protected againstpredation, growth of both species was significantly faster andsurvivership higher at Malgas than at Marcus Island, where C.meridionalis is abundant but A. ater absent. When the musselswere unprotected at Malgas, they were eaten in a few hours.At Marcus Island where rock-lobsters are virtually absent, cagedmussels grow faster than unprotected individuals and survivedlonger. Drilling whelks (mostly Nucella squamosa (Lamarck))were major predators at Marcus. Relative intensity of rock-lobsterpredation and competition between the mussels appear to controlthe structure and diversity of the sublittoral communities atthese sites, rather than physical factors. Growth rate, shellthickness and tolerance of smothering by other species determinewhich species of mussel predominates. (Received 5 April 1988; accepted 11 July 1988)     

Influence of abiotic factors on bacterial proliferation and anoxic survival of the sea mussel Mytilus edulis L.

The effect of several abiotic factors (salinity, temperature and pH) on bacterial proliferation and survival time of the sea mussel Mytilus edulis L. were studied under anoxic incubations. In addition, the presence in the incubation media of ammonium and the volatile fatty acids propionate and acetate, both excreted fermentation products of the bivalve, was tested.Anoxic incubations with seawater diluted with demineralised water showed at the lowest salinity (50% seawater, SW) a significant increase in the capacity of M. edulis to survive anoxia as compared to both 75% SW and control [100% SW, corresponding to 32 practical salinity units (psu)]. Formation of biotic sulphide and ammonium occurred in all incubations. However, bacterial proliferation was postponed by 2-3 days at lowest salinity and accordingly, concentrations of both compounds were lower. Anoxic survival profiles of mussels collected from different habitats in the Dutch Scheldt area, characterised by differences in salinity (range from 17 to 31 psu), corresponded with the above salinity effect. Walsoorden mussels (17 psu) showed the longest (P<0.001) survival time under anoxia (LT₅₀=17.2 days) as compared with Paulina (27 psu) and Wemeldinge (31 psu) mussels (LT₅₀=12.8 and 9.8 days, respectively). Condition index (ratio of soft body weight to shell volume) was not correlated with anoxic survival time in untreated mussels, although this was clearly the case when the antibiotic chloramphenicol was added to the anoxic seawater.Acidification of the anoxic incubation medium had a positive effect on survival time. LT₅₀ values significantly (P<0.001) increased from 10.2 days at pH 8.1 to 11.6 and 11.5 days at pH 7.3 and 6.5, respectively. Biotic sulphide and ammonium accumulation as well as bacterial numbers were significantly lower at pH 7.3 and 6.5 as compared with pH 8.1. Anoxic incubations at 10 °C (LT₅₀=12.0 days) strongly increased survival time as compared to 18 °C (LT₅₀=5.9 days). The benefit of antibiotic addition was also stronger at lower temperature (10 °C).Addition of both propionate and acetate (0.5 mM) displayed no effect on mortality of mussels under anoxia, but ammonium (0.5 mM) caused a negative effect (P<0.001). Biotic sulphide and ammonium concentrations measured in both volatile fatty acid incubations were lower than the control situation, as well as total bacterial numbers.This study shows that environmental factors play a significant role in determining the course of bacterial infection and death of bivalves exposed to anoxia.     

Effects of salinity on solute clearance from the freshwater bivalve, Dreissena polymorpha Pallas

Clearance of polyethylene glycol (PEG), inulin, or dextran that had been injected into the hemolymph of the mussel, Dreissena polymorpha, was measured in animals acclimated to pondwater (PW) or 10% seawater (SW). In addition, we measured the clearance of PEG from mussels acutely transferred into 10% SW and following return to PW after acclimation to 10% SW. Clearance values calculated for PW-acclimated mussels ranged from 2.0 to 3.3 ml (g dry tissue ċ h)^-1 and declined to 0.28 ml (g dry tissue ċ h)^-1 in 10% SW-acclimated animals. Transferring mussels into 10% SW resulted in a reduction in PEG clearance from the blood, coincident with the reduction of osmotic gradient. When 10% SW-acclimated mussels were returned to PW the clearance of PEG increased to rates observed in PW-acclimated animals within 1 h. The PEG clearance remained constant during the re-acclimation to PW even though the osmotic gradient declined from about 100 to 30 mosmol kg^-1. Clearance of the solutes used in this study was likely to be a measurement of renal filtration rate. The clearance values appeared to be maximal when the animals were in PW. The limited capacity to increase clearance in the face of an osmotic challenge may be a critical factor in restricting D. polymorpha to freshwater or lower salinity environments with small ranges in salinity.     

Biomarker responses and accumulation of hazardous substances in mussels (Mytilus trossulus) transplanted along a pollution gradient close to an oil terminal in the Gulf of Finland (Baltic Sea)

Baltic Sea blue mussels (Mytilus trossulus) were used as sentinel organisms to detect the biological effects of chemical contamination in the low salinity environment. Mussels naturally adapted to a salinity of ca. 6.0 PSU were caged for 30 days at four sites along an assumed pollution gradient (salinity ca. 4.5 PSU) in the vicinity of Finland's largest oil refinery and harbor Kilpilahti in the Gulf of Finland. Tissue concentrations and accumulation rates of especially organic contaminants (PAHs, PCBs and organotins) were clearly elevated at the innermost coastal stations near the harbor area. Biological effects of contaminant exposure on caged mussels were evaluated by measuring a suite of biomarkers including catalase, glutathione S-transferase, superoxide dismutase, glutathione reductase, lipid peroxidation, acetylcholinesterase activity and lysosomal membrane stability. Mussels transplanted near the harbor area were able to elevate their antioxidant defense in response to environmental contamination. Reduced morphometric condition index and soft tissue growth rate together with increased lipid peroxidation and low lysosomal membrane stability were also observed at the most contaminated site. The results suggest that caging of M. trossulus for four weeks at lower salinity is a feasible method for the detection of environmental pollution also in low salinity areas of the Baltic Sea.