Effects of temperature and salinity fluctuation on the ammonium excretion and osmoregulation of juveniles of Penaeus vannamei,Boone

This study assesses the effect of temperature and fluctuations in salinity on the nitrogen excretion and osmoregulation of Penaeus vannamei juveniles to determine the lowest stress combination so that these can be used to optimize production of the Mexican strain in culture. The ammonium excretion rate of juveniles acclimated to 20, 24, 28 and 32°C was measured. Fluctuating salinity levels were applied to these animals in a sequence of 40%o, 33, 25, 18, 11, 18, 25, 33 and back to 40%o. The results indicate that when the salinity was reduced from 40 to 11%> the ammonium excretion of the shrimp was reduced. The osmotic concentration of the animals was hyposmotic as the salinity decreased from 40 to 25%o, hyperosmotic during the 18–11–18 in %> interval and hyposmotic as the salinity increased from 25 to 40%> again. The range of isomotic points over this range of salinity was 712–777mmol Kg^‐1. The ammonium excretion of P. vannamei exposed to these experimental conditions can be attributed to the process of osmoregulation because excretion was increased when the shrimp were hyper‐regulating and reduced when they were hypo‐regulating. Based on our results, the animals experience the lowest stress in a temperature between 27 to 30°C and a salinity close to the isosmotic point between 25 ‐ 27%o. We propose that this should prove to be the optimal temperature and salinity regime for culturing the Mexican strain of P. vannamei.     

Effects of temperature, salinity and irradiance on the growth of the red tide dinoflagellate Gyrodinium instriatum Freudenthal et Lee

The effects of temperature, salinity and irradiance on the growth of the red tide dinoflagellate Gyrodinium instriatum Freudenthal et Lee were examined in the laboratory. Exposed to 45 different combinations of temperature (10–30 °C) and salinity (0–40) under saturating irradiance, G. instriatum exhibited its maximum growth rate of 0.7 divisions/day at a combination of 25 °C and a salinity of 30. Optimum growth rates (>0.5 divisions/day) were observed at temperatures ranging from 20 to 30 °C and at salinities from 10 to 35. The organism could not grow at ≤10 °C. In addition, G. instriatum burst at a salinity of 0 at all temperatures, but grew at a salinity of 5 at temperatures between 20 and 25 °C. It is noteworthy that G. instriatum is a euryhaline organism that can live under extremely low salinity. Factorial analysis revealed that the contributions of temperature and salinity to its growth of the organism were almost equal. The irradiance at the light compensation point (I₀) was 10.6 μmol/(m² s) and the saturated irradiance for growth (I_s) was 70 μmol/(m² s), which was lower than I_s for several other harmful dinoflagellates (90–110 μmol/(m² s)).     

Effects of temperature,salinity and their interaction on growth of the benthic dinoflagellate Ostreopsis cf. ovata (Dinophyceae) from Japanese coastal waters

Benthic dinoflagellates of the genus Ostreopsis produce palytoxin (PTX)‐like compounds. The worldwide distributed Ostreopsis ovata/O. cf. ovata is potentially responsible for outbreaks of human health problems around the coasts of tropical, subtropical, and temperate regions. The present study examined growth responses of an O. cf. ovata strain s0662 collected from coastal waters of Japan with 35 different combinations of temperature (15–35°C) and salinity (20–40) and discusses the bloom dynamics of the organism in Japanese coastal environments. The O. cf. ovata strain s0662 tolerated a wide range of temperature (17.5–35°C) and salinity (25–40). Results of a two‐way ANOVA showed significant effects of temperature‐salinity interaction on growth rates and biomass yields of the O. cf. ovata strain (F(24,70) > 127, P < 0.001). The strain showed a maximal growth rate (1.03 divisions day^?1) and biomass yield (240 relative fluorescence) at temperature 25°C and salinity 30. The high growth rates of over 1.0 division day^?1 were obtained in conditions of temperature 25–30°C and salinity 30–35, which indicates that strain s0662 prefers high temperature and salinity conditions. The growth rates of O. cf. ovata under the optimal conditions were higher than those of other benthic toxic‐dinoflagellates, Coolia monotis, Gambierdiscus toxicus, and Prorocentrum lima (Dinophyceae) previously reported. Taken together, we suggest that O. cf. ovata is able to grow faster than the other benthic dinoflagellates in waters of high temperature and salinity. The physiological feature probably confers an ecological advantage on O. cf. ovata in the bloom development during warmer seasons in Japan and may be responsible for outbreaks of PTX‐like poisoning in the region especially during the warmer seasons.     

Growth, maturation and photosynthesis of the brackish water alga Rhizoclonium sp. (Cladophoraceae, Chlorophyta) in relation to salinity

The effects of salinity on growth, maturation and photosynthesis were examined in the filamentous alga Rhizoclonium sp. (Cladophoraceae, Chlorophyta) growing in a brackish water habitat in a canal draining into Tokyo Bay, Japan. In this habitat Rhizoclonium sp. was exposed to a wide salinity range, both daily, 5–23‰ during November 1996, and hourly, 6–24‰ during the spring tide day. From the results of culture experiments, growth and maturation of Rhizoclonium sp. occurred in the wide salinity range of 10–40‰ at 20 μmol photons m‐²s‐¹ at 20°C, but did not occur at salinity of 0‰. Light saturation on the photosynthesis‐irradiance curve at 20°C at 20‰ was reached at 100 μmol photons m‐²s‐¹, which is characteristic for shade‐adapted algae. On the photosynthesis‐salinity curve at 20°C at saturated irradiance (160 μmol photons m‐²s‐¹), the net photosynthetic rate increased with increasing salinity up to 30‰ but decreased at 40‰. On the photosynthesis–salinity curve at 20°C at 20 μmol photons m‐²s‐¹ (at near in situ irradiance), the photosynthetic rates were almost the same in the salinity range from 0 to 40‰. Therefore, this species is able to grow, reproduce and photosynthesize with a relative efficiency in a wide salinity range, which shows that it is well adapted to a brackish water environment.     

Influence of temperature, salinity and nutrient limitation on yessotoxin production and release by the dinoflagellate Protoceratium reticulatum in batch-cultures

The toxic dinoflagellate Protoceratium reticulatum (Claparède & Lachmann) Buetschli is recurrently present in the Adriatic sea. It is the producing organism of yessotoxin (YTX) and some of its analogues and thus its presence in seawater often results in shellfish farm closure for long periods. However, molluscs become highly toxic also at the presence of low cell concentrations, due to the high YTX content present in most algal strains. As no data were available on the environmental conditions favouring growth and YTX production by Adriatic P. reticulatum strains, in the present work, we investigated the effect of nutrient limitation, salinity and temperature on growth and YTX content in P. reticulatum cultures. Liquid chromatography–mass spectrometry (LC–MS) analyses were carried out to determine YTX production as well as the difference between the YTX amount retained in cells and that released in growth medium, in order to relate cell content to excretion mechanisms. The toxin content was determined in cells collected at the stationary phase, since both toxin production and release were found to be higher in this growth stage than in the exponential phase. As for nutrient-effect, a severe P-limitation strongly affected cell growth and favoured toxin accumulation, as consequences of both impaired cell division and lower toxin release. N-limited cultures, on the contrary, had a toxin content similar to controls and the highest percentage of release. P. reticulatum was confirmed to be tolerant towards salinity changes as it could grow at salinity values in the range of 22–42. The highest YTX production was observed at intermediate salinity values (32) whereas toxin release, expressed as percentage of the total amount produced, decreased as salinity increased. P. reticulatum growth was impaired in cultures kept at 26 °C in respect to those grown at 16 and 20 °C. YTX release decreased as temperature increased; however, cells kept at 26 °C displayed a very high YTX content. The environmental implications of these physiological behaviours highlight that farmed molluscs can become less toxic in colder waters at lower salinity values.     

AUTECOLOGICAL STUDIES ON THE MARINE DIATOM RHIZOSOLENIA FRAGILISSIMA BERGON. I. THE INFLUENCE OF LIGHT,TEMPERATURE, AND SALINITY1

The influence of 113 combinations of temperature (9, 12, 18, 25, 30 C), salinity (5–35 ‰ at 5 ‰ intervals), and light (4 levels) on the mean daily cell division rate (K) of the Narragansett Bay clone of Rhizosolenia fragilissima was examined following appropriate preconditioning. Growth did not occur below 9 C, but was excellent (K =～1.2) under certain combinations of light and salinity at 12, 18, and 25 C. The optimal salinity of 20–25 ‰ was temperature independent. Growth was not measurable at 5 ‰, although survival occurred. At 20 ‰ and 1200 ft-c, K increased approximately 1.8-fold from 0.65 to ～1.2 between 9 and 18–25 C. The optimal light intensity was generally 600 ft-c, although several light-temperature-salinity trends were found. At 10 ‰ at all temperatures, the mean daily division rate decreased with increasing light above 600 ft-c, a response found at all salinities at 12 C, but not at other temperatures. Between 15 and 25 ‰, at 18 and 25 C, mean growth was independent of light intensity; at 30–35 ‰ a direct relationship with light may be present with maximum growth occurring at 1200–1800 ft-c. The in situ and in vitro responses of Rhiz. fragilissima to salinity and the optimum and upper temperature levels are in general agreement. However, growth failure below 9 C in vitro is at odds with reports that natural populations occur even at ?1.11 C. The questions of to what extent this discrepancy reflects the occurrence of thermal clones, different taxa, and/or experimental artifacts are briefly discussed. It is suggested that naturally occurring populations found below 9 C might be designated as Rhiz. fragilissima f. faeröensis, and that Rhiz. fragilissima f. bergonii be used for populations growing at higher temperatures, until this matter is resolved. Observations on auxospore formation are presented.     

Effects of salinity on growth and survival of African sharptooth catfish (clarias gariepinus) larvae

Growth and survival of replicate batches of African sharptooth catfish (Clarias gariepinus) larvae were monitored in 0, 2.5, 5.0, 7.5 and 10 ppt salinity. No significant differences in mortality or growth rate were evident between 0 and 5 ppt salinity. At 7.5 ppt mortality rate was higher and larval growth rate declined in comparison to the lower salinities. At 10 ppt all larvae died within 48 hours. The condition factor of the larvae similar between 0–2.5 ppt and displayed a declining trend between 2.5–7.5 ppt. Osmoconcentratkm of blood plasma of C. gariepinus in fresh water was 280 ± 20 mOsm/kg which is equivalent to 9.5 ppt salinity. It was concluded that 0–2.5 ppt is the optimal sclinity range for larval rearing and that short-term exposure to higher salinities (2.5–7.5 ppt) could be effective in the treatment of ectoparasitic diseases.     

盐度对长牡蛎和近江牡蛎及其杂交稚贝生长和存活的影响

2011年8月以长牡蛎自繁组GG(Crassostrea gigas♀×C.gigas♂),近江牡蛎自繁组AA(C.ariakensis♀×C.ariakensis♂)、正交组GA(Crassostrea gigas♀×C.ariakensis♂)、反交组AG(C.ariakensis♀×C.gigas♂)为实验材料,开展了稚贝对盐度的适应性研究。结果发现长牡蛎的最适生存盐度为15—35,最适生长盐度为25—35;近江牡蛎的最适生存盐度为10—25,最适生长盐度为20—25;GA的最适生存盐度为15—30,最适生长盐度为15—30,AG的最适生存盐度为20—30,最适生长盐度为20—25。GG对低盐度敏感,AA对高盐度敏感,AG具有高盐度存活的杂种优势,在盐度30时,中亲杂种优势HG×A为13.32,单亲杂种优势HGA和HAG分别为1.89和27.88,在盐度40时,HAG上升到400,GA和AG都不具有生长优势。杂种稚贝对盐度适应介于双亲之间,且表现出一定程度的父系遗传特点。     

Effects of salinity on synthesis of DNA,acidic polysaccharide,and ichthyotoxin in Gymnodinium breve

A Florida red tide organism, Gymnodinium breve Davis, an unarmored dinoflagellate, was grown in enriched sea water media at salinities 20–43% and constant illumination. Use of lowest (23%) and highest (43%) salinities resulted in death within 24 hr of inoculation, though good growth was obtained at all intermediate salinities (29–39%), in accord with field observation. Rates of synthesis of DNA, acidic polysaccharide and ichthyotoxin were determined as a function of salinity and growth constant (K₁₀). The relative rate of' synthesis of DNA or polysaccharide increased linearly with growth constant. Mean cell volumes, determined during log-phase growth, showed a positive correlation with doubling time. Hemolytic activity was detected in cell extracts only at high toxin concentrations (0.35–2.05 mg of ichthyotoxin). No significant difference was noted in hemolytic activity of extracts of cells grown in high (34%) or low (26%) salinity. The rate of toxin synthesis showed a linear decrease with the rate of DNA or polysaccharide synthesis.     

Distribution ofVibrio cholerae in two Florida estuaries

The distribution ofVibrio cholerae was examined in 2 Florida estuaries, Apalachicola and Tampa Bay.Vibrio cholerae serotype non-01 was the most abundant serotype, being isolated from 45% of the oyster samples, 30% of the sediments, 50% of the waters, and 75% of the blue crabs.Vibrio cholerae serotype 01 was isolated from only one oyster sample. Strong linear correlations betweenV. cholerae and temperature, salinity, or the other physical/chemical parameters measured,Escherichia coli, or fecal coliforms were not observed, but a range of temperatures and salinities appeared relevant to the distribution of the organism. The organism was present in the highest concentrations when salinities were 10‰–25‰ and temperatures were 20?C–35?C.In vitro growth curves of 95V. cholerae environmental isolates further supported that 10‰–25‰ was an ideal salinity range for the organisms. The results suggest thatV. cholerae is a widely distributed organism in the nutrient-rich warm waters of the Gulf Coast estuaries.     

Phenotypic plasticity of four Chenopodiaceae species with contrasting saline–sodic tolerance in response to increased salinity–sodicity

It is unknown whether phenotypic plasticity in fitness‐related traits is associated with salinity–sodicity tolerance. This study compared growth and allocation phenotypic plasticity in two species with low salinity–sodicity tolerance (Chenopodium acuminatum and C. stenophyllum) and two species with high salinity–sodicity tolerance (Suaeda glauca and S. salsa) in a pot experiment in the Songnen grassland, China. While the species with low tolerance had higher growth and allocation plasticity than the highly tolerant species, the highly tolerant species only adjusted their growth traits and maintained higher fitness (e.g., plant height and total biomass) in response to increased soil salinity–sodicity, with low biomass allocation plasticity. Most plasticity is “apparent” plasticity (ontogenetic change), and only a few traits, for example, plant height:stem diameter ratio and root:shoot biomass ratio, represent “real” plasticity (real change in response to the environment). Our results show that phenotypic plasticity was negatively correlated with saline–sodic tolerance and could be used as an index of species sensitivity to soil salinity–sodicity.     

The role of water level and salinity in the regulation of Juncus gerardi populations in former ricefields in southern France

Abstract. In the Rhône delta (southern France) Juncus gerardi is a dominant, strongly aggregating species in artificially flooded former rice fields. In order to explain this pattern, the effects of water depth, salinity and their interaction were measured on (1) seed germination and seedling development and (2) vegetative growth of J. gerardi in a controlled-environment experiment. The germination pattern of J. gerardi was affected by salinity. Low salinity (2 g/l NaCl) delayed germination while moderate salinity (12 g/l NaCl) reduced germination rate. In contrast, the germination of J. gerardi was not affected in the range of water depths tested (i.e. 0–10cm). Salinity negatively affected the development of below-ground parts, shoots and inflorescences. This negative effect of salinity on the vegetative growth of J. gerardi was amplified when combined with flooding. Flooding with fresh water (0–20 cm depth) did not limit biomass production during the experiment. However, a decrease in the ratio of below-ground/above-ground dry weight at deeper water depths suggests a limitation of the vegetative propagation of J. gerardi under prolonged flooding conditions. This hypothesis is supported by the negative correlation between the cover of J. gerardi and water depth found in an abandoned rice field. The limitation on seedling recruitment imposed by salinity and the depression of vegetative growth of J. gerardi due to a combination of salinity and water depth could explain the aggregate distribution of J. gerardi in former rice fields.     

A study on early tolerance of Mactra chinensis philippi to salinity

In order to evaluate the early tolerance of Mactra chinensis to salinity, the treatments of salinity gradients and salinity gradual changes were set in this study, and the post growth and development of juveniles were analyzed in recovery experiment, respectively. The result showed that the optimum hatching of zygotes was found at a salinity from 24 to 32, which is narrower than that of larvae (20–32); a slight of low salinity (16–32) will benefit the early growth and development of M. chinensis; at planktonic and creeping stages, low salinity stress (20) was conducive to promoting the growth of juvenile M. chinensis philippi; 4, 48 was the ultimate salinity of M. chinensis; The range of early tolerance of larvae M. chinensis philippi to salinity can be widened through a short period of salinity acclimation.     

Salt-tolerant and plant growth-promoting bacteria isolated from Zn/Cd contaminated soil: identification and effect on rice under saline conditions

The bacteria of PDMCd0501, PDMCd2007, and PDMZnCd2003 were isolated from a Zn/Cd contaminated soil. They were classified as salt-tolerant bacteria in this experiment. The bacteria had indole-3-acetic acids (IAA) production, nitrogen fixation, and phosphate solubilization, under 8% (w/v) NaCl condition. Biochemical test (API 20E) and 16S rDNA sequencing identified PDMCd2007 and PDMCd0501 as Serratia sp. and PDMZnCd2003 was Pseudomonas sp. The effect of Pseudomonas sp. PDMZnCd2003 on the germination and seedlings of Oryza sativa L.cv. RD6 was determined under a salinity of 0–16 dS/m. The salinity levels of 4–16 dS/m affected to decrease germination and seedlings of rice. Comparison between uninoculated and inoculated system, however, Pseudomonas sp. PDMZnCd2003 had a negative impact on the rice growth. This unexpected effect was a case that should be concerned and studied further before application as a plant growth-promoting bacteria (PGPB).     

A metabolic study to decipher amino acid catabolism-directed biofuel synthesis in Acetoanaerobium sticklandii DSM 519

Acetoanaerobium sticklandii DSM 519 is a hyper-ammonia-producing anaerobe. It has the ability to produce organic solvents and acids from protein catabolism through Stickland reactions and specialized pathways. Nevertheless, its protein catabolism-directed biofuel production has not yet been understood. The present study aimed to decipher such growth-associated metabolic potential of this organism at different growth phases using metabolic profiling. A seed culture of this organism was grown separately in metabolic assay media supplemented with gelatin and or a mixture of amino acids. The extracellular metabolites produced by this organism were qualitatively analyzed by gas chromatography–mass spectrometry platform. The residual amino acids after protein degradation and amino acids assimilation were identified and quantitatively measured by high-performance liquid chromatography (HPLC). Organic solvents and acids produced by this organism were detected and the quantity of them determined with HPLC. Metabolic profiling data confirmed the presence of amino acid catabolic products including tyramine, cadaverine, methylamine, and putrescine in fermented broth. It also found products including short-chain fatty acids and organic solvents of the Stickland reactions. It reported that amino acids were more appropriate for its growth yield compared to gelatin. Results of quantitative analysis of amino acids indicated that many amino acids either from gelatin or amino acid mixture were catabolised at a log-growth phase. Glycine and proline were poorly consumed in all growth phases. This study revealed that apart from Stickland reactions, a specialized system was established in A. sticklandii for protein catabolism-directed biofuel production. Acetone–butanol–ethanol (ABE), acetic acid, and butyric acid were the most important biofuel components produced by this organism. The production of these components was achieved much more on gelatin than amino acids. Thus, A. sticklandii is suggested herein as a potential organism to produce butyric acid along with ABE from protein-based wastes (gelatin) in bio-energy sectors.

     

Effect of salinity on the distribution, growth, and toxicity of Karenia spp.

The first recorded bloom of Karenia spp., resulting in brevetoxin in oysters, in the low salinity waters of the Northern Gulf of Mexico (NGOMEX) occurred in November 1996. It raised questions about the salinity tolerance of Karenia spp., previously considered unlikely to occur at salinities <24 psu, and the likelihood that the bloom would reoccur in the NGOMEX. Salinity was investigated as a factor controlling Karenia spp. abundance in the field, using data from the NGOMEX 1996 bloom and Florida coastal waters from 1954 to 2004, and growth and toxin production in cultures of Karenia brevis (Davis) G. Hansen and Moestrup. During the NGOMEX bloom, Karenia spp. occurred much more frequently at low salinities than in Florida coastal waters over the last 50 years. The data suggest that the NGOMEX bloom started on the NW Florida Shelf, an area with a higher frequency of Karenia spp. at low salinities than the rest of Florida, and was transported by an unusual westward surface current caused by Tropical Storm Josephine. The minimum salinity at which growth occurred in culture ranged between 17.5 and 20 psu, but the optimal salinity ranged between low values of 20 or 25 and high values of 37.5–45 psu, depending on the clone. The effect of salinity on toxin production in one clone of K. brevis was complex, but at all salinities brevetoxin levels were highest during the stationary growth phase, suggesting that aging, high density blooms may pose the greatest public health threat. The results demonstrate that Karenia spp. can be a public health threat in low salinity areas, but the risk in the NGOMEX is relatively low. No bloom has occurred since the 1996 event, which was probably associated with a special set of conditions: a bloom along the Florida Panhandle and a tropical storm with a track that set up a westward current.     

THE EFFECT OF SALINITY AND TEMPERATURE ON THE GERMINATION OF POLYMORPHIC SEEDS AND GROWTH OF ATRIPLEX TRIANGULARIS WILLD.

Polymorphic seeds of Atriplex triangularis were germinated at various temperatures (5–15 C, 5–25 C, 10–20 C, 20–30 C) and salinity regimes (0 to 1.5% NaCl) in order to determine their germinability and early seedling growth under these conditions. Larger seeds generally had a higher germination percentage in saline medium. The rate and percentage of germination decreased with increased salinity stress. A thermoperiod of 25 C day and 5 C night, 12 hr/12 hr, temperature enhanced germination of seeds. Early seedling growth is promoted in larger seeds at lower salinity, and at high-day and low-night temperatures. Polymorphic seeds have different physiological requirements which provide alternative situations for seed germination in natural habitats.     

Effects of temperature, salinity and irradiance on the growth of the harmful red tide dinoflagellate Cochlodinium polykrikoides Margalef (Dinophyceae)

The effects of temperature, salinity and irradiance on the growthof the harmful red tide dinoflagellate Cochlodinium polykrikoideswere examined in the laboratory. From 60 different combinationsof temperature (10–30°C) and salinity (10–40)under saturated irradiance, C. polykrikoides exhibited its maximumspecific growth rate of 0.41 day^-1 at a combination of 25°Cand salinity of 34. Optimum growth rates of >0.3 day^-1 wereobserved at temperatures ranging from 21 to 26°C and atsalinities from 30 to 36. The organism did not grow at temperatures10°C and only grew at salinities >30 if the temperaturewas >15°C. It was able to grow in temperatures rangingfrom 15 to 30°C and at salinities from 20 to 36. These valuesclosely resembled those observed for this species in situ. Itappears as if C. polykrikoides is a stenohaline organism thatprefers high salinities, indicative of offshore waters. Temperaturehad the greatest influence on the growth rate, followed by salinity,and then the interaction between temperature and salinity. Theoptimum irradiance for growth was >90 µmol m^-2 s^-1.Photoinhibition did not occur at 230 µmol m^-2 s^-1, whichwas the maximum irradiance used in this study.     

Pyramimonas amylifera Conrad (Prasinophyceae): seasonal dynamics of a wild population, and the effects of temperature and salinity on growth and survival in culture

Temperature, salinity and abundance of Pyramimonas amyliferawere monitored over a 1-year period in a tidal salt marsh pool.The organism reached two peaks of abundance, the first in latefall before ice covered the pool, and the second in late winterafter the ice had melted. Cysts, but no oc-toflagellate stagesof this organism, were found in the pool in summer. The resultsof growth experiments on a clone of this organism isolated fromthe pool indicate that a temperature between 10 and 15 C isoptimal. A temperature between 20 and 25 C is the maximum tolerableby this clone. The "short-term" salinity tolerance range ofthis clone was found to decrease with increasing temperature,a phenomenon which could affect the fitness of the organismas a tide pool inhabitant. The field and laboratory data indicatethat although temperature and salinity were factors affectingthe abundance of P. amylifera in the pool, other factors notconsidered in the study must have also been important. ^*Present address: Department of Biology, University of SouthFlorida, Tampa, Florida, U.S.A. 33620. (Address for reprints)