Der einfluß einer Vorbehandlung mit konstanten und wechselnden Temperaturen auf die Hitzeresistenz von Gammarus salinus und Idotea balthica

The crustaceans Gammarus salinus Spooner and Idotea balthica Pallas live in brackish waters and are capable of tolerating a variety of temperature and salinity conditions. Thus far, the capacity for non-genetic adaptation of such euryplastic animals has only been tested at different levels of constant temperatures. If exposed to both constant (8°, 14° or 20°C) and fluctuating (daily fluctuation: 8°?20°C) temperatures, the tested individuals reveal significant differences in heat resistance which become apparent within 12 h. G. salinus and I. balthica exhibit reasonable (meaningful) heat resistance, i.e., a positive correlation between the degree of heat resistance and the level of adaptation temperature (AT). Following a shift in AT (8° → 20°C or 20° → 8°C) the degree of resistance changes rather fast. This leads, under fluctuating temperature conditions, to diurnal changes in the degree of heat resistance. I. balthica also shows an endogenous diurnal periodicity of its heat resistance. In G. salinus, long-term exposure (2 to 4 weeks) to fluctuating temperatures [duration of temperature change: 2 h (Δ/2 h)] produces, during the day, a mean resistance value which coincides with the value obtained for AT 14°C-controls. This fact results from temperature-independent adaptation speeds (same after decrease and increase of AT). However, fast temperature change (ΔT/1 h) during exposure to fluctuating temperatures leads to a significant augmentation of heat resistance, presumably due to additional stress; such fast temperature changes are less well tolerated than slow fluctuations (ΔT/2 h). In I. balthica, low ATs are less efficient in terms of heat resistance than high ATs (great difference between AT=14° and 20 °C; small difference between AT=8° and 14 °C). In males, lowering of AT from 20° to 8 °C results, within the first 12 h, to faster loss of heat resistance than is the case for gain in heat resistance after AT increase from 8° to 20 °C. However, after prolonged exposure to the new ATs, completion of readaptation is temperature-independent. Under conditions of fluctuating temperatures (ΔT/2 h) resistance increases beyond the mean value (AT=14 °C). Further increase in resistance can be obtained through fast temperature changes (ΔT/1 h). In G. salinus, which occupies habitats with more extensive temperature fluctuations, the responses studied are less pronounced than in I. balthica.     

Heat resistance of gametes of marine invertebrates in relation to temperature conditions under which the species exist

It is the purpose of this paper to elucidate the possible role of the heat resistance level of mature gametes and embryos of poikilotherms in the adaptation of a species to environmental temperature conditions. Within a species, heat resistance of gametes does not undergo any recognisable changes even in the presence of significant fluctuations in temperature. Evidence in support of this statement was obtained on gametes of invertebrates belonging to different populations of the same species collected in different seasons, and on invertebrates maintained under different temperatures. The heat resistance of gametes is correlated with the degree of thermophily of the species concerned. Species living under similar temperature conditions exhibit minimal, if any, differences in heat resistance. Hence, the heat resistance level of their gametes is a function of temperature conditions of formation and existence of the species as a whole. During the ontogenesis of poikilotherms, eggs, zygotes and early stages of embryonic development are most susceptible to heat injury. The upper thermal limit for the normal development of eggs and embryos is only 1 to 3C^o higher than the temperatures encountered under natural conditions. It is concluded that the heat resistance level of gametes and embryos represents an adjustment to temperatures at which spawning, fertilisation and earlier embryonal development occur. Temperatures which, throughout the year, exceed the upper thermal limit or remain below the lower thermal limit for the development of embryos, act as limiting factors for the species' distribution.     

Intraspecific physiological variability of the gastropod Littorina saxatilis related to the vertical shore gradient in the White and North Seas

 Physiological responses to desiccation and temperature stress as well as behavioural responses to fast and abrupt environmental changes were investigated in high- and low-shore Littorina saxatilis (Olivi) from several populations from the White and North Seas. Variations in evaporation rates, resistance to air exposure and to acute and chronic temperature stress between animals from different shore levels were similar in White and North Sea periwinkles, consistent with the adaptive nature of these variations. High-shore snails were found to be able to conserve body water reserves better, to resist higher temperatures and to survive longer under conditions of combined temperature and desiccation stress than their low-shore counterparts. In a temperature range of 25 to 35 °C, the rate of evaporative water loss was positively correlated with temperature in low-shore snails while being largely temperature-independent in high-shore snails. Median lethal time during air exposure in L. saxatilis was negatively but not linearly related to the temperature of exposure. In a temperature range of 30 to 38 °C, the resistance to heat exposure in air was only slightly dependent on the temperature, with Q ₁₀ = 1.4 for the median lethal time; the heat resistance dropped drastically at temperatures above 38 °C, with Q ₁₀ = 593.8. This suggests different mechanisms of temperature resistance in different parts of the studied temperature range. In contrast, behavioural response to extreme salinity fluctuations was not uniform in the high- and low-shore periwinkles from the White and North Seas, which may reflect specific environmental conditions at different shore levels in the two areas studied. Observed physiological and behavioural variations are discussed from the viewpoint of different adaptive strategies employed by eulittoral and eulittoral-fringe animals within populations of a single species. Received: 13 December 1999 / Accepted: 11 April 2000     

Der einfluß von temperaturänderungen anf enzyme der fischmuskulatur. Versuche mit Rhodeus amarus

The enzyme activities estimated in the muscles of Rhodeus amarus (Bloch) may vary according to the kind of muscle, age and sex of the test individuals, as well as with the time of day, and the season. Oxygen consumption of individuals acclimated to different temperatures was tested at 22°C. At low adaptation temperatures no adaptation was found; at high adaptation temperatures, however, compensation could be ascertained. In view of the considerable fluctuation of the enzyme activities, estimated from individuals adapted to different temperatures, a relation to certain adaptation types, established by Precht (1961b, 1968), is hardly possible. During the first days following sudden or slow changes of adaptation temperature (increase or decrease) more or less marked fluctuations of enzyme activities were obtained. Later, however, in accordance with the proceeding adaptation, a new, labile balance was established. Temperature changes represent a physiological stress even within normal temperature ranges. This fact requires general attention in studies on biological processes. Disturbance of a newly established balance of enzyme activities can be obtained, when test fishes are exposed to high temperatures. This finding may be of importance in regard to the heat resistance of the animals.     

Resistenzadaptation bei gehemmeter Proteinbiosynthese. Versuche mit Actinomycin D an dem Fisch Rhodeus amarus

Rhodeus amarus acclimated to 10° or 20°C die at 31.7° or 36.4°C, respectively (cessation of operculum movements). After raising the adaptation temperature (AT) from 10° to 20°C, adaptation is complete after 8 days. The toxicity of actinomycin D, injected intraperitoneally, is AT-dependent (e.g. at 5°C, LD_{50–7 days}=0.8 μg/g fish; at 25°C, LD_{50–7 days}=0.35 μg/g fish). In the following experiments 0.5 μg actinomycin/g fish were used. After actinomycin-injection, RNA-values in white dorsal muscle decreased about 50% within 12 h and the values of control individuals were finally attained after 16 days. Following an AT-change from 10° to 20°C, DNA-values in the white dorsal muscle increased about 10%, RNA-values about 30%, within 12 h. However, in fish injected intraperitoneally with actinomycin, no increase in DNA or RNA was noticed. Actinomycin injection per se causes increased heat resistance. This process lasts 10 days. If AT is raised now from 10° to 20°C, the new resistance level is reached later. The control fish gain resistance at a rate of about 1 C°/day during the first days after the temperature change. Actinomycin-treated individuals, however, exhibit an increase of 0.25 C°/day. Inhibition of resistance adaptation due to proteinbiosynthesis-inhibitors supports the view that protein synthesis is of importance for adjustments in heat resistance of intact animals.

     

Positive buoyancy in eel leptocephali: an adaptation for life in the ocean surface layer

Many planktonic organisms have adaptations such as floats or lighter substances to obtain buoyancy to help them remain in the surface layer of the ocean where photosynthetic primary production occurs and food is most abundant. The almost totally transparent eel larvae, called leptocephali, are a unique member of the planktonic community of the surface layer, but their ecology and physiology are poorly understood. We conducted a comparative study on the specific gravity of planktonic animals including 25 taxa of 7 phyla of marine invertebrates and 6 taxa of leptocephali (vertebrate) to gain a broad perspective on the buoyancy of the eggs and larval stages of the Japanese eel. The specific gravity values of the various freshly caught marine invertebrate taxa varied widely from 1.020 to 1.425, but leptocephali had some of the lowest values (1.028–1.043). Artificially cultured live leptocephali had even greater buoyancies with specific gravities of 1.019–1.025 that were close to or lower than seawater, and their buoyancy showed ontogenetic changes among the different early life history stages. Leptocephali appear to have a unique mechanism of buoyancy control by chloride cells all over body surface through osmoregulation of body fluid contained in the extracellular matrix of transparent gelatinous glycosaminoglycans filling their bodies. This adaptation is likely a key factor for their survival by helping them to remain in the surface layer where food particles are the most abundant, while being transparent for predator avoidance. The ontogenetic change in buoyancy of eel eggs, leptocephali and glass eels likely enhances their larval survival, transport, and recruitment to terrestrial freshwater habitats.     

Long-term reactions of plants and macroinvertebrates to extreme floods in floodplain grasslands

Extreme summertime flood events are expected to become more frequent in European rivers due to climate change. In temperate areas, where winter floods are common, extreme floods occurring in summer, a period of high physiological activity, may seriously impact floodplain ecosystems. Here we report on the effects of the 2002 extreme summer flood on flora and fauna of the riverine grasslands of the Middle Elbe (Germany), comparing pre- and post-flooding data collected by identical methods. Plants, mollusks, and carabid beetles differed considerably in their response in terms of abundance and diversity. Plants and mollusks, displaying morphological and behavioral adaptations to flooding, showed higher survival rates than the carabid beetles, the adaptation strategies of which were mainly linked to life history. Our results illustrate the complexity of responses of floodplain organisms to extreme flood events. They demonstrate that the efficiency of resistance and resilience strategies is widely dependent on the mode of adaptation.     

Vergleichende ökologisch-physiologische Untersuchungen zur zellulären Kälteresistenz mariner Evertebraten

Cellular freezing and chilling resistances of different marine bivalve species have been measured comparatively, using isolated pieces of gill tissues. The species-specific resistance values correspond to the ecological behaviour and the geographical distribution of the species. Among marine animals from subarctic and boreal regions, cellular freezing resistance is significantly higher in species living, during the whole year, in the upper littoral than in bottom dwellers or sublittoral forms. Tissues of tropical littoral bivalves are very sensitive to freezing. Similar responses are obtained in deepwater species of the temperate zone. Studies on geographically separated populations of species from both sides of the Atlantic Ocean demonstrate small differences in cellular freezing resistance; no genetically fixed distinctions could be recognized. Among species within the same littoral habitat, those suffering from mass mortalities in extremely severe winters also exhibit comparatively lower cellular chilling and freezing resistances. In littoral bivalves from normal sea water, considerable seasonal variations of cellular freezing resistance occur; such variations are very small in specimens from brackisk waters. Maximum freezing resistance results from adaptation to low temperature combined with high salivity. The adaptation time required for reaching the final level of resistance depends on temperature and salinity. Also, the considerable increases in cellular freezing resistance caused by exposure to air, or to oxygen-deficient water, or by different organic compounds, are modified by temperature and salinity conditions during pretreatment. The subtropical-tropical species Chione cancellata, exhibits “meaningful” adaptation of cellular chilling resistance when the adaptation temperature is changed from 10° to 23.5°C; however, no comprehensible change in cellular freezing resistance occurs at the same time. Increased calcium contents of the external medium affect cellular chilling and freezing resistances of marine bivalves differently. Quick effluxes of aldolase (from cytoplasm) and of acid phosphatase (from lysosomes) after freezing and thawing of isolated gills indicate damage to membranes before cellular injuries are recognized by microscopical observations. Partial inactivation of acid phosphatase by exposure to freezing and thawing is only found after “death” of the tissue.     

BALB／C鼠睾丸组织中冷诱导RNA结合蛋白的cDNA克隆与序列分析

冷诱导RNA结合蛋白(Cold inducible RNA-binding protein,CIRP)在多种冷应激细胞(包括重组中国仓鼠卵巢细胞)中被发现.迄今为止,冷应激对活体生物基凶表达的影响还未见报道.和细胞相比,生物体具有更加复杂的冷应激调节机制.本研究以冷处理的BALB/C鼠为实验动物,从其睾丸组织巾克隆出了CIRP的cDNA.结果表明,CIRP在生物体中能够被低温诱导,可能防止生物体遭受冷损伤.根据克隆的cDNA所推测的氨基酸序列与GenBank上公布的小鼠、大鼠、人类、牛蛙、美西螈、非洲爪蟾胚胎细胞和卵母细胞的CIRP氨基酸序列同源性分别为100%、99.40%、95.5%、67.4%、58.4%、76.9%和79.1%.这表明CIRP在生物进化过程中是高度保守的,可能具有多种生理功能.因此,这一研究将为探索人类和动物冷应激分子机制创立系统试验模型和奠定新的实践基础.图5参14     

No evidence for homeoviscous adaptation in intertidal snails: analysis of membrane fluidity during thermal acclimation, thermal acclimatization, and across thermal microhabitats

Many eurythermal organisms alter composition of their membranes to counter perturbing effects of environmental temperature variation on membrane fluidity, a process known as homeoviscous adaptation. Marine intertidal gastropods experience uniquely large thermal excursions that challenge the functional integrity of their membranes on tidal and seasonal timescales. This study measured and compared membrane fluidity in marine intertidal snail species under three scenarios: (1) laboratory thermal acclimation, (2) thermal acclimatization during a hot midday low tide, and (3) thermal acclimatization across the vertical intertidal zone gradient in temperature. For each scenario, we used fluorescence polarization of the membrane probe DPH to measure membrane fluidity in individual samples of gill and mantle tissue. A four-week thermal acclimation of Tegula funebralis to 5, 15, and 25°C did not induce differences in membrane fluidity. Littorina keenae sampled from two thermal microhabitats at the beginning and end of a hot midday low tide exhibited no significant differences in membrane fluidity, either as a function of time of day or as a function of thermal microhabitat, despite changes in body temperature up to 24°C within 8 h. Membrane fluidities of a diverse group of snails collected from high, middle, and low vertical regions of the intertidal zone varied among species but did not correlate with thermal microhabitat. Our data suggest intertidal gastropod snails do not exhibit homeoviscous adaptation of gill and mantle membranes. We discuss possible alternatives for how these organisms counter thermal excursions characteristic of the marine intertidal zone.     

Species and speciation in poikilothermal animals

On the basis of current scientific information related to intraspecific and interspecific variability of eco-physiological properties at the individual (organismic) and subindividual (tissues, cells, and molecules) levels and his own experimental data, the author comes to the conclusion that eco-physiological adaptation is one of the major processes determining speciation. During sequential multi-step adaptation at the most sensitive and plastic levels of organisation (whole organisms and their labile cells and proteins) to changed abiotic (physico-chemical) environmental factors, the latter directly affect the conservative proteins and polynucleotides that maintain the species' genetic information. Transition from phenotypical to genotypical changes may be achieved if the organisms have attained the limit of their phenotypical plasticity, via selection at cellular and molecular levels. The high rate of cellular mytotic division and a promiment rise in the speed of interrelated DNA-RNA protein synthesis under sudden and profound environmental changes may account for the high rates of speciation indicative of cataclysmic climatic changes. Evolutionary morphological changes are considered to follow physiological changes. The adaptive nature of morphological peculiarities in higher taxonomic categories (type, class, order, family; more seldom genus) may be accounted for by the selection of phenotypes possessing morphological peculiarities best suited to the ecological niches of the species concerned. These peculiarities (although often neutral to physiological changes that have determined the speciation) are transferred from species to species, manifesting both historical relationship and morphological unity. The suggested scheme of speciation is in accord with the conceptions of the intermittent character of speciation, which can proceed only if extreme, directed, climatic changes cover a larger portion of the species' area. As the organisms' organisation becomes more complex during phylogenesis, intraspecific variability decreases; this trend manifests itself in the progressive stabilization of body shape and other morphological properties, and in the increase of eco-physiological stability of cells and proteins.     

杨树抗旱性研究进展

The drought resistance of woody plants, in particular, Populus, was reviewed in this paper. Studies about drought resistance of Populus mostly focused on changes in growth properties, physiological adaptation and biochemical aspects, but a few on molecular biology. The indexes of drought adaptation and productivity were analyzed and these indexes could be employed to identify drought resistance of woody plants. Combination of such different approaches will, hopefully, give us a more complete understanding of the various regulatory mechanisms in trees than what we may have today. With development of the molecular biology of woody plants, the sluties on stress resistance of Populus which was regarded as a model plant, are summarised. Ref 96     

Distribution and temperature adaptation in the teleost fish genus Gibbonsia

Along the California coast there are three intertidal species of the genus Gibbonsia (G. elegans, G. metzi, G. montereyensis). These species have distinct but overlapping distributions. Collections were made seasonally from three areas. Each collection was divided into two groups — a critical thermal maximum and minimum were determined for one group and the other group was tested after a 3 week acclimation period. The three species showed genetically different adaptation abilities and these were correlated with species differences in latitudinal distributions. The species that experiences the widest seasonal temperature range proved capable of anticipatory adjustment to temperature while the two experiencing small seasonal changes showed only reactive adjustments. the species with the widest distribution showed the greatest ability to adapt to temperature extremes. After 1 week acclimation all three species demonstrated different mechanisms for heat and cold adaptation.     

Facultative lecithotrophy during larval development of the burrowing shrimp Callianassa tyrrhena (Decapoda: Callianassidae)

Survival, developmental and consumption rate (Artemia nauplii ingested per day) as well as predation efficiency (ingested per available Artemia nauplii) were studied during the larval development of the shallow-water burrowing thalassinid Callianassa tyrrhena (Petagna, 1792), which exhibits an abbreviated type of development with only two zoeal stages and a megalopa. The larvae, hatched from berried females from S. Euboikos Bay (Aegean Sea, Greece), were reared at 10 temperature–food density combinations (19 and 24 °C; 0, 2, 4, 8 and 16 Artemia nauplii d⁻¹). Enhanced starvation resistance was evident: 92 and 58% of starved zoeas I molted to zoea II, while metamorphosis to megalopa was achieved by 76 and 42% of the hatched zoeas at 19 and 24 °C, respectively. The duration of both zoeal stages was affected by temperature, food density and their interaction. Nevertheless, starvation showed different effects at the two temperatures: compared to the fed shrimp, the starved zoeae exhibited accelerated development at 19 °C (8.4 d) but delayed metamorphosis at 24 °C (5.9 d). On the other hand, both zoeal stages were able to consume food at an increased rate as food density and temperature increased. Predation efficiency also increased with temperature, but never exceeded 0.6. Facultative lecithotrophy, more pronounced during the first zoeal stage of C.tyrrhena, can be regarded as an adaptation of a species whose larvae can respond physiologically to the different temperature–food density combinations encountered in the wide geographical range of their natural habitat. Received: 28 February 1998 / Accepted: 21 October 1998     

Acquisition and loss of cold-tolerance in adult barnacles (Balanus balanoides) kept under laboratory conditions

In the laboratory, Balanus balanoides (L.) barnacles maintained without food at 5°C over the winter to summer period remained cold-tolerant. Winter animals maintained at 5°C and fed Artemia nauplii under a controlled light-dark regime until mid-summer lost this cold-tolerance. Summer animals, maintained without food at 5° or 15°C until midwinter, became cold-tolerant. Summer and winter animals subjected to increased (or decreased) ambient salinity for 48 h showed a small decrease (or increase) in their lower median lethal temperature (MLT—defined as the temperature at which 50% of the animals die after 18 h exposure to air). Summer animals subjected to desiccation for 48 h also showed a small decrease in their lower MLT. It is concluded that the seasonal changes in cold-tolerance of adult barnacles are probably induced by a combination of environmental factors including food availability, light intensity, day-length and changes in ambient sea-water temperatures. Development of cold-tolerance in the winter did not depend upon fertilisation. Changes in intra-cellular solute concentration which accompany adaptation to changes in ambient salinity or desiccation do not appear to be related to the seasonal changes in cold-tolerance.     

Survival of microscopic stages of a perennial kelp (<Emphasis Type="Italic">Macrocystis pyrifera</Emphasis>) from the center and the southern extreme of its range in the Northern Hemisphere after exposure to simulated El Niño stress

Many organisms survive stressful conditions through a tolerant life history stage. The life history known as the alternation of generations is typical of temperate kelps, producing diploid macroscopic stages, and both haploid and diploid microscopic stages, with the haploid stages thought to be stress tolerant. The survival of microscopic stages of the giant kelp Macrocystispyrifera during El Niño has been suggested, yet has never been tested. This mechanism could be critical for population persistence, particularly at the southern limit of the range in the Northern Hemisphere, which is greatly impacted by El Niño conditions. The purpose of this study was to determine if microscopic stages of giant kelp could survive and recover from El Niño-type conditions and whether those from a population near its southern limit were more tolerant than a population at the center of its range. Microscopic stages were exposed to a laboratory simulation of potential El Niño conditions (high temperature, with and without light and nitrate) for 8 weeks and then allowed to recover at optimal conditions (low temperature and high nitrate) for 8 weeks, while controls were left at optimal conditions the entire 16 weeks test period. Haploid developmental stages from both populations survived and recovered from stressful conditions with no population level effect, suggesting haploid stress-tolerance may be widespread. The more advanced the developmental stage, and the presence of nitrate, resulted in significantly greater recovery for haploids. Yet, none of these stages were able to go on to produce sporophytes, whereas all controls did. There was a large population-level effect for diploids, however, with only microscopic diploid stages (embryonic sporophytes) from the southern-limit population recovering from El Niño simulated stress, suggesting ecotypic adaptation for microscopic sporophytes. Diploid recovery was significantly greater with light. We propose that the diploid stage is the most likely to survive and recover after El Niño conditions, as it would avoid obligate egg and sperm encounters after the stress period. The survivorship of the microscopic diploid in a seed bank analogue may be how the isolated southern-limit populations are able to recover after mass disappearance during El Niño.     

Vulnerability and Resilience of Tropical Forest Species to Land‐Use Change

Abstract: We provide a cross‐taxon and historical analysis of what makes tropical forest species vulnerable to extinction. Several traits have been important for species survival in the recent and distant geological past, including seed dormancy and vegetative growth in plants, small body size in mammals, and vagility in insects. For major past catastrophes, such as the five mass extinction events, large range size and vagility or dispersal were key to species survival. Traits that make some species more vulnerable to extinction are consistent across time scales. Terrestrial organisms, particularly animals, are more extinction prone than marine organisms. Plants that persist through dramatic changes often reproduce vegetatively and possess mechanisms of die back. Synergistic interactions between current anthropogenic threats, such as logging, fire, hunting, pests and diseases, and climate change are frequent. Rising temperatures threaten all organisms, perhaps particularly tropical organisms adapted to small temperature ranges and isolated by distance from suitable future climates. Mutualist species and trophic specialists may also be more threatened because of such range‐shift gaps. Phylogenetically specialized groups may be collectively more prone to extinction than generalists. Characterization of tropical forest species’ vulnerability to anthropogenic change is constrained by complex interactions among threats and by both taxonomic and ecological impediments, including gross undersampling of biotas and poor understanding of the spatial patterns of taxa at all scales.     

Metabolic responses of the squat lobster (Pleuroncodes monodon) larvae to low oxygen concentration

Squat lobster populations found in the Humboldt Current System over the continental shelf from ~28 to 37°S release pelagic larvae in sub-surface cold (~11 °C) hypoxic waters. Larvae subsequently spread throughout the water column encountering both normoxic and hypoxic conditions. We analyzed some short- and long-term responses of Pleuroncodes monodon larval metabolism to hypoxia at 11 °C. Routine and postprandial aerobic respiration rates were lower in hypoxia than in normoxia for all zoeal stages. Zoea V oxyconformed, while megalopae oxyregulated down to very low oxygen concentrations. Throughout zoea I development, the rate of nitrogen (protein) accumulation in zoea I was lower, and C:N ratios were higher under hypoxic conditions than in normoxia. Citrate synthase (CS) and malate dehydrogenase (MDH) apparent specific activities (as indicators of aerobic and metabolic potentials, respectively) decreased and remained at the same level, respectively, throughout zoea I reared under hypoxic conditions. Anaerobic to aerobic potential (lactate dehydrogenase (LDH)/CS) was higher in organisms reared under hypoxia, and MDH/LDH potential ratios were characteristic of organisms tolerant to hypoxia. In spite of P. monodon zoea endurance and metabolic adaptations to decreasing oxygen tensions, intense hypoxia as such of their release site would affect their overall condition especially toward the end of the molt cycle. Our results indicate the importance of considering the interaction between environmental oxygen variability and recruitment success.     

Growth of sea bass,Dicentrarchus labrax,larval and juvenile stages and their otoliths under quasi-steady temperature conditions

The relationship between somatic growth and growth of otoliths of sea bass larvae, postlarvae and juveniles under relatively steady temperature conditions was studied. Larvae were incubated at the constant ambient temperature of 13.5°C, whereas postlarvae and juveniles were reared at a comparatively steady temperature ranging from 18.6 to 20.4°C, with a mean of 19.67°C. The patterns of both somatic and otolith growth were found to be similar. Differentiated data on larvae length and otolith diameters indicated three periods of change in their growth rates. Since temperature was kept relatively steady during the experiment, and larvae fed ad libitum, these periods could be attributed with relative certainty to intrinsic changes which occur during stage-specific periods of growth. The third period of change in both growth rates indicates a specific phase of growth during metamorphosis. The changes in growth rates, as well as the raw time series of the growth of both larval lengths and otolith diameters, may be described by higher order polynomials with a high degree of probability levels. A non-linear relationship between body length and otolith diameters was established, indicating positive allometric growth of otoliths. It was also observed that the coefficient of allometric growth changed at the time estimated for the end of metamorphosis. Thus, a non-linear relationship and changes in the coefficients of allometry should be borne in mind when back-calculating somatic growth from the growth of otoliths.     

Effects of nitrate on the diurnal vertical migration,carbon to nitrogen ratio,and the photosynthetic capacity of the dinoflagellate Gymnodinium splendens

A non-thecate dinoflagellate, Gymnodinium splendens, was studied in a 12 d laboratory experiment in 2.0x0.25 m containers in which light, temperature, and nutrients could be manipulated. Under a 12 h light: 12 h dark cycle, the dinoflagellates exhibited diurnal vertical migrations, swimming downward before the dark period began and upward before the end of the dark period. This vertical migration probably involved geotaxis and a diel rhythm, as well as light-mediated behavior. The vertical distribution of nitrate affected the behavior and physiology of the dinoflagellate. When nitrate was present throughout the container, the organisms resembled those in exponential batch culture both in C:N ratios and photosynthetic capacity (P_max); moreover, they migrated to the surface during the day. In contrast, when nitrate was depleted, C:N ratios increased, P_max decreased, and the organisms formed a subsurface layer at a depth corresponding to the light level at which photosynthesis saturated. When nitrate was present only at the bottom of the tank, C:N ratios of the population decreased until similar to those of nutrient-saturated cells and P_max increased; however, the dinoflagellates behaved the same as nutrient-depleted cells, forming a subsurface layer during the light period. Field measurements revealed a migratory subsurface chlorophyll maximum layer dominated by G. splendens. It was just above the nitracline during the day, and in the nitracline during the night, which concurs with our laboratory observations.