Distribution of the brine shrimps Parartemia zietziana Sayce and Artemia salina (L.) along a salinity and oxygen gradient in a South Australian saltfield

SUMMARY. The seasonal distribution of Parartemia zietziana and Artemia salina was studied in a South Australian saltfield. P. zietziana occurred alone at salinities from 112 to 214%‰ and A. salina occurred alone at salinities above 285%‰; the two species overlapped in the range 214 to 285%‰. Respiration experiments indicated that A. salina had a lower 'critical' oxygen concentration than P. zietziana , apparently due to the presence of haemoglobin in A. salina . This may result in an adaptive advantage at high salinity and low dissolved oxygen.     

Interactions between a salt marsh native perennial (Salicornia virginica) and an exotic annual (Polypogon monspeliensis) under varied salinity and hydroperiod

An exotic grass invades salt marshes of southern California in very wet years and where there are sewage spills or urban runoff. A series of growth-chamber, mesocosm, and greenhouse experiments explored whether soil salinity and/or waterlogging could explain invasion patterns. In all experiments, salinity significantly affected the growth and distribution of Polypogon monspeliensis (rabbit-foot grass, an exotic annual grass) and Salicornia virginica (pickleweed, a native perennial succulent). High salinities caused a greater reduction in seed germination rates for P. monspeliensis than for S. virginica, indicating that high salinity limits establishment and the spread of this exotic grass. At Tijuana Estuary, fresh water inputs to tidal mesocosms lowered soil salinities, increased cover of P. monspeliensis, and decreased cover of S. virginica. Polypogon monspeliensis outcompeted S. virginica under all salinity and hydrology treatments in the greenhouse experiment. Seasonally-low soil salinities caused by winter runoff and anthropogenic fresh water inputs are the likely factors controlling annual variations in the distribution of P. monspeliensis in southern California salt marshes. Our understanding of the causes of invasion is readily applicable to management: local invasions may be reversed by adding salt, and larger scale problems could be avoided by reinstating more natural hydrologic regimes.     

Germination ecology of coastal plants in relation to salt environment

Responses of seed germination to salinity were examined using 37 species collected from salt marshes, cliffs, and fore (unstable) and hind (stable) sand dunes along Japanese coasts. For comparison, seed germination of nine inland species was also examined. The soil salinities in salt marshes ranged from 150 to 300 mmol/L NaCl, whereas those in fore and hind dunes ranged from 0 to 150 mmol/L NaCl, with a few exceptions. Cliff soils showed relatively high salinities up to 300 mmol/L NaCl. Ciff and foredune soils that encountered a typhoon and storm showed high salinities >300 mmol/L NaCl. Salt tolerance in seed germination of coastal plants was ordered by comparing the responses of percentage and rate of germination to salinity conditions up to 200 mmol/L NaCl, being in the order of salt marsh>cliff>foredune≅hind dune≅inland. Thse results indicate that salt tolerance in seed germination of coastal plants is closely related to the salinity conditions of their habitats. Germination experiments under favorable conditions showed that a high percentage of the seeds of salt marsh species germinate rapidly, those of diff species germinate slowly and those of foredune species exhibit a low percentage and low rate of germination. It seems that these germination characteristics contribute to the success of germination at the ‘safe site’ and the subsequent survivorship of emerged plants in their natural habitats.     

Energetics of the muricid gastropod Thais (Nucella) lapillus (L.)

Multivariate analysis of the physiological energetics of Thais (Nucella) lapillus (L.) was used to predict combinations of salinity and temperature at which scope for growth and reproduction will be positive. The scope for growth correlated positively with change in energy content at 15 and 20°C. The results suggest that energetic constraints set limits to capacity adaptation at ≈ 22‰ salinity, in agreement with field observations of the species distribution limit within estuaries. The zone of resistance adaptation is limited to salinities 15‰, probably because of an inefficiency in volume regulation at lower salinities. Growth of these dogwhelks is suppressed at minimum winter (5°C) and maximum summer (20°C) temperature, largely due to suppression of feeding. Constraints imposed by physiological energetics are important for an understanding of the ecology of this species, and may explain some features of seasonal change in behaviour, e.g. aggregations for purposes of egg-laying in the winter.     

Kinetics of the Anti-oxidant Response to Salinity in the Halophyte Cakile maritima

The effects of NaCl stress on the activity of anti-oxidant enzymes (superoxide dismutase, catalase (CAT),peroxidase (POD),ascorbate peroxidase (APX), monodehydroascorbate reductase, dehydroascorbate reductase (DHAR), and glutathionereductase (GR)), anti-oxidant molecules (ascorbate and glutathione), and parameters of oxidative stress (malondialdehyde(MDA), electrolyte leakage, and H_2O_2 concentrations) were investigated in Cakile maritima, a halophyte frequent along theTunisian seashore. Seedlings were grown in the presence of salt (100, 200, and 400 mmol/L NaCI). Plants were harvestedperiodically over 20 days. Growth was maximal in the presence of 0-100 mmol/L NaCl. At 400 mmol/L NaCl, growthdecreased significantly. The salt tolerance of C. maritima, at moderate salinities, was associated with the lowest values ofthe parameters indicative of oxidative stress, namely the highest activities of POD, CAT, APX, DHAR, and GR and high tissuecontent of ascorbate and glutathione. However, prolonged exposure to high salinity resulted in a decrease in anti-oxidantactivities and high MDA content, electrolyte leakage, and H_2O_2 concentrations. These results suggest that anti-oxidantsystems participate in the tolerance of C. maritima to moderate salinities.     

Kinetics of the Anti-oxidant Response to Salinity in the Halophyte Cakile maritima

The effects of NaCl stress on the activity of anti-oxidant enzymes （superoxide dismutase, catalase （CAT）, peroxidase （POD）, ascorbate peroxidase （APX）, monodehydroascorbate reductase, dehydroascorbate reductase （DHAR）, and glutathione reductase （GR））, anti-oxidant molecules （ascorbate and glutathione）, and parameters of oxidative stress （malondialdehyde （MDA）, electrolyte leakage, and H2O2 concentrations） were investigated in Cakile maritima, a halophyte frequent along the Tunisian seashore. Seedlings were grown in the presence of salt （100, 200, and 400 mmol/L NaCl）. Plants were harvested periodically over 20 days. Growth was maximal in the presence of 0-100 mmol/L NaCl. At 400 mmol/L NaCl, growth decreased significantly. The salt tolerance of C. maritima, at moderate salinities, was associated with the lowest values of the parameters indicative of oxidative stress, namely the highest activities of POD, CAT, APX, DHAR, and GR and high tissue content of ascorbate and glutathione. However, prolonged exposure to high salinity resulted in a decrease in anti-oxidant activities and high MDA content, electrolyte leakage, and H2O2 concentrations. These results suggest that anti-oxidant systems participate in the tolerance of C. maritima to moderate salinities.     

Osmoregulatory disturbances induced by the parasitic barnacle Loxothylacus texanus (Rhizocephala) in the crab Callinectes rathbunae (Portunidae)

The osmoregulatory response of the blue crab Callinectes rathbunae parasitized with the rhizocephalan barnacle Loxothylacus texanus, and subjected to sudden salinity changes, was experimentally measured in the laboratory. Parasitized and control crabs were exposed to salinity changes every 3 h and their hemolymph osmolality measured. Two experiments, one with increasing salinity conditions (5‰, 12‰, 19‰, 25‰) and a second one with decreasing salinities (35‰, 25‰, 15‰, 5‰) were conducted. The results show that L. texanus significantly alters the hemolymph osmolality of C. rathbunae maintaining it at lower than normal levels. In the increasing salinity trial, the hypoosmotic hemolymph condition of parasitized crabs was present at all salinities tested, whereas in the decreasing salinity trial a significant effect was found only at salinities of 5‰ and 15‰. Since C. rathbunae is constantly subjected to abrupt salinity changes in the tropical estuaries where it occurs, moving into high salinity areas may be the only way to cope with the impact of L. texanus.     

Survival, activity and feeding ability of Baltic cod (Gadus morhua) yolk-sac larvae at different salinities

Due to unfavourable conditions (declines in salinity and water oxygen content) in the spawning areas, there has been a considerable decrease in the Baltic cod stock since the beginning of the 1980s, and consequently a decrease in catches. In order to examine the feasibility of introducing yolk-sac larvae in areas of low salinity to improve the stock, laboratory experiments were performed on the effects of salinity on the survival, level of activity and feeding ability of larvae. Yolk-sac larvae from spawning cod caught off northern Gotland, Sweden, were exposed to four different salinities: 10 and 15%○ (salinities of the main spawning areas); and 5 and 7%○ (salinities in the Bothnian Sea and the Baltic proper respectively).
The survival of yolk-sac larvae was high at all salinities, even though there was an indication of higher mortality at low salinities in less viable larval groups. No differences were found in swimming speed or feeding ability at the four salinities, but a significant difference in vertical distribution was recorded. There were significant differences in survival, vertical distribution and feeding ability among larval groups, which indicates that larval quality or viability is of greater importance for larval survival than salinity, in the range of 5–15%○.     

高浓度钾抑制杜氏盐藻生长的生理机制

在含１ｍｏｌ／ＬＮａＣｌ的杜氏盐藻（Ｄｕｎａｌｉｅｌａｓａｌｉｎａ（Ｄｕｎａｌ）Ｔｅｏｄ．）培养液中加入５０ｍｍｏｌ／Ｌ以上的ＫＣｌ可观察到Ｋ＋对杜氏盐藻生长有明显的抑制作用,而当ＫＣｌ达１００ｍｍｏｌ／Ｌ时,杜氏盐藻的生长被完全抑制。另一方面,当培养液中缺乏Ｋ＋时,杜氏盐藻的生长也被显著抑制。在正常培养条件下,伴随着杜氏盐藻的生长,培养液的ｐＨ由８左右升高至１０左右,而高浓度Ｋ＋则显著抑制杜氏盐藻培养液ｐＨ的升高;而在培养液ｐＨ为７．０至１０．０的范围内,不同ｐＨ对杜氏盐藻的生长无明显影响。将杜氏盐藻在高浓度Ｋ＋条件下预处理１２ｈ以上,杜氏盐藻的光合放氧速率显著下降,光合速率下降的程度与Ｋ＋浓度的高低和预处理的时间长短呈正相关。高浓度Ｋ＋处理也引起杜氏盐藻叶绿素含量的显著下降。对经高浓度Ｋ＋预处理的杜氏盐藻的光合放氧速率与培养液中ｐＨ变化同时进行测定的结果表明,Ｋ＋抑制杜氏盐藻光合速率的同时也显著抑制了光照条件引起的培养液ｐＨ的上升。实验结果表明,Ｋ＋抑制杜氏盐藻光合作用以及抑制杜氏盐藻生长与Ｋ＋影响跨盐藻质膜的质子运输之间可能存在一定关系。     

Effects of salinity on growth and cation accumulation of Sporobolus virginicus (Poaceae)

Optimal growth of euhalophytes requires moderate concentrations of salt and, in dicotyledons, is associated with succulence and accumulation of Na(+) in plant tissues. However, reports of salt-stimulated growth in monocotyledons are rare. Relative growth rate (RGR), biomass accumulation, and water content were studied in Sporobolus virginicus (Poaceae), a C(4) chloridoid grass, grown hydroponically with different concentrations of NaCl. Cation concentrations were determined by atomic absorption spectrophotometry. Optimal growth occurred at 100-150 mmol/L NaCl and was not dependent on nitrogen levels or accompanied by accumulation of Na(+) in leaves. Biomass accumulation and RGR in plants grown at 450 mmol/L NaCl were greater than in plants grown at 5 mmol/L. The Na?:?K ratios were lower in leaves than in roots, indicating discrimination in Na(+) and K(+) transport. Secretion of Na(+) increased from 166.5 to 336.7 mmol · g(-1) dry biomass · d(-1) as the NaCl concentration of the nutrient solution increased from 125 mmol/L to 450 mmol/L. Water concentrations of leaves and shoots were significantly greater in plants grown at optimal levels of salinity than in plants grown at lower or higher salinities. These results demonstrate salt-stimulated growth in a monocotyledon.     

Effects of High K+ and Alkaline pH on Ultrastructure of Dunaliella salina Chloroplasts

It was reported that the growth of Dunaliella salina Teod. cultured in medium containing 1 mol/L NaC1 was almost completely inhibited by the addition of 100 mmol/L KC1. The high K+ (100 mmol/L KC1) treatment also significantly inhibited the photosynthetic rate of D. salina and decreased chlorophyll contents in algae. This study focuses on possible effects of high K+ or alkaline pH on the ultrastructural change of chloroplasts in D. salina. After D. salina was cultured in a medium containing 100 n,anol/L KC1 or in a medium with alkaline pH for 8 to 10 days, dramatic ultrastructural changes occurred in the chloroplasts including thylakoid swelling, volume increase of chloroplast, and significant accumulation of starch grains in chloroplasts. The results are consistent with our previous report indicating that the ultrastmctuml changes in chloroplast under high K + or alkaline pH may lead to an inhibitory effects on photosynthesis and overall growth of D. salina.     

The performance of the leaf mining microlepidopteran Bucculatrix maritima (Stt.) on the salt marsh halophyte,Aster tripolium (L.), exposed to different salinity conditions

Summary The performance of phytophagous insects is influenced by the nutritional quality of the food plant, which may vary with environmental conditions. Hardly any information exists on food-plant mediated effects of variable soil salinity on the performance of phytophagous insects. Conspicuous differences in salinity levels, however, are found in soils of intertidal wetlands such as salt marshes and mangroves. The growth of larvae of Bucculatrix maritima, a leaf miner of the salt marsh halophyte Aster tripolium, was studied on the host plant along the salinity gradient of the Westerschelde estuary (S.W. Netherlands). In addition, its performance on A. tripolium grown on low or high salinity culture medium was investigated experimentally. Although salinity conditions significantly influenced the chemistry of the host plants, insect performance seemed almost unaffected, although near the mouth of the estuary high environmental salinities may have caused some inhibition of larval growth. The results contrast with our previous studies on the stem-borer Agapanthia villosoviridescens, which showed that growth and development was conspicuously influenced by the changing characteristics of Aster tripolium along the estuarine salinity gradient. The location-dependent qualities of halophytes in an estuary thus appear to have species-specific effects on insect performance. We hypothesize that this phenomenon contributes to the existence of non-identical distribution patterns of phytophagous insects associated with the same halophyte in an estuary.     

Survival and development of horseshoe crab (Limulus polyphemus) embryos and larvae in hypersaline conditions

The horseshoe crab Limulus polyphemus spawns in the mid- to upper intertidal zone where females deposit eggs in nests below the sediment surface. Although adult crabs generally inhabit subtidal regions of estuaries with salinities from 5 to 34 ppt, developing embryos and larvae within nests are often exposed to more extreme conditions of salinity and temperature during summer spawning periods. To test whether these conditions have a negative impact on early development and survival, we determined development time, survival, and molt cycle duration for L. polyphemus embryos and larvae raised at 20 combinations of salinity (range: 30-60 ppt) and temperature (range: 25-40 degrees C). Additionally, the effect of hyperosmotic and hypoosmotic shock on the osmolarity of the perivitelline fluid of embryos was determined at salinities between 5 and 90 ppt. The embryos completed their development and molted at salinities below 60 ppt, yet failed to develop at temperatures of 35 degrees C or higher. Larval survival was high at salinities of 10-70 ppt but declined significantly at more extreme salinities (i.e., 5, 80, and 90 ppt). Perivitelline fluid remained nearly isoosmotic over the range of salinities tested. Results indicate that temperature and salinity influence the rate of crab development, but only the extremes of these conditions have an effect on survival.     

Physiological Mechanisms of Growth inhibition by Concentrated Potassium in Dunaliella Salina

It was observed in our preliminary experiments that the growth of Dunaliella salina (Dunal) Teed. cultured in medium containing 1 mol/L NaC1 was almost completely inhibited by the addition of 100 mmol/L KC1. This study was focused on elucidating the physiological mechanisms by which high K+ inhibits D. salina growth. Under the control conditions, the pH of the medium rapidly increased from 8 to 10 along with the growth of D. salina. However, addition of 100 mmol/L KCI significantly inhibited the increase of medium pH. The results suggested that the growth of D. salina may require a low environmental of H + concentration or be related to the H + transport into the D. salina cells. Interestingly, D. salina cultured in various media with different pH buffered with 40 mmol/L Tris-HC1 (or Tris-NaOH) did not show any significant difference in the growth rates. This result brings up the question on the previous hypothesis that Na+/H+ antiport plays a major role in Na + extrusion in D. salina. The photosynthetic rate of D. salina was not inhibited immediately following the addition of high K+ in the reaction medium, but it was significantly inhibited after the pretreatment of algae with high K+ for 12 hours or longer. The results from simultaneous measurements of O2 evolution of D. salina and the changes in pH of the medium revealed that the inhibitory effect of high K + on D. salina growth was somehow associated with K+ effect on pH changes in the medium. The high K+ treatment of D. salina also resulted in significant decrease of chlorophyll contents in the algae. It is concluded that the inhibitory effects of high K + on photosynthesis of D. salina may, at least partially, account for the growth-inhibition of D. salina growth by high K+; the inhibitory effects of high K+ on D. salina photosynthesis may result from the influence of K + on H + transport across the plasma membranes of D. salina cells.     

Proteomic analysis of blue light-induced twining response in Cuscuta australis

The parasitic plant Cuscuta australis (dodder) invades a variety of species by entwining the stem and leaves of a host and developing haustoria. The twining response prior to haustoria formation is regarded as the first sign for dodders to parasitize host plants, and thus has been the focus of studies on the host-parasite interaction. However, the molecular mechanism is still poorly understood. In the present work, we have investigated the different effects of blue and white light on the twining response, and identified a set of proteins that were differentially expressed in dodder seedlings using a proteomic approach. Approximately 1,800 protein spots were detected on each 2-D gel, and 47 spots with increased or decreased protein levels were selected and analyzed with MALDI-TOF-MS. Peptide mass fingerprints (PMFs) obtained for these spots were used for protein identification through cross-species database searches. The results suggest that the blue light-induced twining response in dodder seedlings may be mediated by proteins involved in light signal transduction, cell wall degradation, cell structure, and metabolism.     

The effect of salinity on different developmental stages of an endemic annual plant, Aster laurentianus (Asteraceae)

Salinity reduces substrate water potential, thereby restricting water and nutrient uptake by plants; salinity may also cause ionic imbalance and toxicity. Because substrate salinity fluctuates through the growing season, a plant may be exposed to different salinity levels, at various stages of development, with potentially significant consequences on population dynamics. Here, we present the results of a study of the effect of substrate salinity on seed germination, seedling emergence, and growth of Aster laurentianus, an annual marsh plant, endemic to the Gulf of St. Lawrence and potentially threatened. Seed germination was reduced in low salt concentration (10 g sea salt/L) and completely inhibited by salinity levels >/=20 g sea salt/L. However, this inhibiting effect was reversible: seeds from the salt treatments germinated readily after being washed in distilled water. Though seedling emergence was diminished at low salinity levels, postemergence survival was little affected. Plant growth was reduced, but net carbon assimilation rate was not affected by high salinity levels. Increased root respiration and respiratory costs associated with salt tolerance might have contributed to lower C accumulation at higher salinity levels. All developmental processes considered are thus negatively affected by substrate salinity, with potentially significant consequences on population abundance and distribution in salt marshes. Yet, the tolerance of this species to high salinity levels after seedling emergence is remarkable. Seed germination represents a major bottleneck in the species life cycle, potentially controlling local distribution and abundance in the natural habitat.     

Long-term hyposaline and hypersaline stresses produce distinct antioxidant responses in the marine alga Dunaliella tertiolecta

Tolerance to salinity stress in higher plants correlates to levels of antioxidant enzymes and/or substrates. Do hyperosmotic and hypoosmotic stress induce antioxidant responses in salt tolerant algae, and if so, are these responses the same for both excess and minimal salinity? To answer these questions, cultures of the marine alga Dunaliella tertiolecta (Chlorophyta) were grown in seven salinities covering a 60-fold range from 0.05 to 3.0 mol/L NaCl. Long-term effects of salinity on growth and antioxidant parameters were determined. Growth rates were reduced at the salinity extremes (0.05 mol/L NaCl and 3 mol/L NaCl) indicating the cultures were stressed. The levels of six antioxidant enzymes and three antioxidant substrates were quantified at these growth salinities. Compared to growth at optimum salinities (i.e. 0.2-0.5 mol/L NaCl), high salinities produced a 260% increase in monodehydroascorbate reductase, a doubling of ascorbate peroxidase activity and a three-fold increase in the rate of dark respiration. Cells acclimated to low growth salinities (hyposaline stress, i.e. < 0.2 mol/L NaCl) showed major increases in glutathione and alpha-tocopherol coupled with decreases in Fv/Fm ratios and in total and reduced ascorbate compared to moderate and high external salinities. Cell volumes remained unchanged, except at the lowest salinity where they doubled. Catalase, superoxide dismutase, dehydroascorbate reductase and glutathione reductase activities were not altered by extreme salinities. The involvement of oxidative stress at both salinity extremes is implied by the alterations in antioxidant enzymes and substrates, but the specific changes are very different between hypo and hypersaline stresses.