Horizontal distribution and dominant species of heteropods in the East China Sea

This article discusses the horizontal distribution and dominantspecies of heteropods in the East China Sea. The ecologicalcharacteristics of heteropods and their adaptability to theenvironments were also considered. Oceanographic census wascarried out in the East China Sea (23°30 '33° N and118°30'128° E) in four seasons from 1997 to 2000. Itwas found that the total abundance showed obvious seasonal variations.It peaked in autumn with a mean value of 21.03 ind. (100 m³)^–1,followed by summer (4.89 ind. (100 m³)^–1). The lowestabundance occurred in winter and spring. As to the horizontaldistribution, abundance in summer and autumn was higher in thenearshore than in the offshore of the East China Sea. In winterand spring, heteropods were barely found in the northern nearshore.Three dominant species were observed in four investigated seasons,in which only Atlanta rosea dominated in winter, spring andsummer while Atlanta peroni and Atlanta lesueuri mainly dominatedin autumn. These two dominant species observed in autumn exhibiteda rather higher occurrence frequency than A. rosea. Temperaturewas found to be a major influencing factor whereas salinitywas a minor one. Comparing their adaptability, A. rosea cansurvive in a wider temperature range (1628°C), which enablesit to dominate in four seasons, while A. peroni survives ina relatively narrow temperature range (1928°CC) and therange for A. lesueuri was even more narrow (2128°CC). Moreover,A. rosea was also adapted to a wider range of salinity. However,the abundance of A. rosea in autumn was lower than those ofA. peroni and A. lesueuri. It can be thereby inferred that themultiplication speed of A. rosea was lower than the other twospecies within the same favorable temperature range. Due totheir adaptability to high salinity, the distribution of heteropodswas closely related to the domain of the Taiwan Warm Currentand Kuroshio. Especially for A. peroni and A. lesueuri, theirhigh abundance areas are always indicative of the lasting existenceof strong warm currents. The negative values of aggregationindices indicated relatively even distribution of heteropodsin the East China Sea. The high abundance area (31°00' N,126°00' E) of heteropods in autumn is on the migration pathwayof the mackerel (Scomber japonicus Houttuyn). Thus, there isalso a fishing ground of the mackerel. This suggested that thehigh abundance area of heteropods in autumn is important tothe fisheries in the East China Sea. Comparing with the historicalrecords, the abundance of heteropods appeared to increase inthe past 40 years. This may be a result of strengthened warmcurrents due to global warming.     

Characteristics and Importance of Heterogeneous ice Nuclei Associated With Citrus Fruits

The freezing behaviour and relative importance of heterogeneousice nuclei in affecting supercooling of Citrus sinensis fruitswere studied. The size of an ice nucleation active (INA) Pseudomonassyringae pool inhabiting fruits was positively correlated withthe nucleation temperature (NT) of the plant tissue, with amean of 369 log colony forming units (CFU) fruit^–1 atNT–25C. The INA bacterial pool was responsible for 23%of the nucleation events occurring at this temperature, and29% were attributed to an additional nucleating source. Thelatter was sensitive to bacterial ice nucleation inhibitors,it occupied a different microniche from that of P. syringaenuclei, yet was neither a fungus nor any of the bacterial strainsever reported as active. Treatment with an ice nucleation inactivebacterium antagonistic to INA bacteria, a lentil lectin, a protease,and guanidine reduced mean nucleation temperatures (MNT) offruits to –258, –266, –421, and–452C,respectively, compared to a MNT–167C for the controls.Thus, the citrus-associated nucleator apparently contained activeproteinaceous components but was void of carbohydrate-like groupsreportedly encountered at or near the bacterial ice nucleatingsite. Despite the different origins of citrus nuclei, bacterialnucleation inhibitors reduced nucleation in the field by 50%at NT––25C, an effect probably exerted throughthe proteinaceous site possessed by both nuclei. Key words: Citrus, ice nucleation, INA bacteria, supercooling     

Seasonal variation in the species composition of tintinnid cilates in Hiroshima Bay, the Seto Inland Sea of Japan

Seasonal changes in the species composition of tintinnid ciliateswere examined based on time-series samples taken at 2 week intervalsover a 3 year period in Hiroshima Bay, the Seto Inland Sea ofJapan. The maximum abundance of total tintinnids over the entireperiod was 5.7 x 10³ indi viduals l^– Among 32 speciesidentified, a consistent seasonal occurrence was recognizedin 22 species. The relationships between various environmentalfactors and the abundance of each species of tintinnids wereanalyzed using principal component analysis From this analysis,the abundance of many tintinnids was revealed to be associatedwith temperature, the <20 µm size fraction of chlorophylla and water column stability, but not with the <20 µmsize fraction of chlorophyll a, nor with salinity. From theseresults, tintinnid species were divided into five associationtypes: species whose abundance increased with increasing temperature,decreasing temperature, nanophytoplankton abundance, increasingwater column mixing, or increasing water stratification coupledwith low temperature.     

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.     

Distinct Cellular and Organismic Responses to Salt Stress

We have compared metabolic effects of high salinity betweenplants and cell suspension cultures from the facultative halophyteMesembryanthemum crystallinum (common ice plant). This plantshows developmentally-programmed inducibility for a switch fromC₃-photosynthesis to CAM (Crassulacean Acid Metabolism). Themetabolic switch is enhanced by environmental factors such asdrought, low temperature, and, most effectively, soil salinity.CAM induction is dependent on organized leaf tissue and cannotbe elicited by salt stress in suspension culture cells. In contrast,the accumulation of proline [Thomas et al. (1992) Plant Physiol.98: 626] is induced by NaCl in cultured cells as well as inplants and must be considered a cellular response to stress.We have extended our observations to include another trait ofsalt- and low-temperature-stress responses in the ice plant,the accumulation of putative osmoprotective sugars and sugaralcohols. In whole plants the cyclic sugar alcohol, pinitol,accumulates to amounts that approach 1 M during stress, whilein suspension cells no increase in sugar alcohols is observed.The distribution of carbon to different sugars is markedly differentbetween cells and plants under stress. Particularly obviousis the distinction between cell types in the different compositionof sugars and polyols, as exemplified by the epidermal bladdercells of ice plants. Ion contents and the content of sugarsand sugar alcohols of bladder cells indicate that Na⁺, Cl^–,pinitol and an unknown carbohydrate compound provide osmoticpressure in these cells, while organic anion concentrationsare low. With the ice plant, we conclude that cells in culturemimic only partly the stress response mechanisms of intact plantsand we hypothesize that communication between different tissuesis required to mount a complete environmental stress response. ⁴ Present address: Department of Botany Oklahoma State University,Stillwater, OK, 74078, U.S.A.     

The Effects of Temperature on 86Rb Uptake by Two Species of Chlamydomonas (Chlorophyta, Chlorophyceae)

⁸⁶Rb uptake was examined in two species of unicellular greenalgae, Chlamydomonas nivalis isolated from snow, and a cellwall-less mutant of the temperate freshwater Chlamydomonas reinhardii.In C. reinhardii cells grown at 20°C and cooled rapidlyto 0°C, ⁸⁶Rb uptake was abolished. Cells cooled rapidlyto –5°C in the absence of ice accumulated ⁸⁶Rb veryrapidly but the time course of this uptake suggested non-selectiveaccumulation through a damaged plasmalemma. Cells grown at 8°Cwere viable, able to divide and motile; they showed no signsof cold-shock and ⁸⁶Rb uptake, albeit slow, was measurable at–5°C in the absence of extracellular ice. Cells ofC. nivalis grown at 20°C were damaged at sub-zero temperaturesalthough they did show an enhanced ⁸⁶Rb uptake at 0°C. Cellsgrown at 5°C were able to accumulate ⁸⁶Rb from media undercooledto -5°C in the absence of extracellular ice, and again showedenhanced uptake at 0°C. The process of acclimation to lowtemperature appears to differ in the two species. Key words: Chlamydomonas, temperature, ⁸⁶Rb uptake, membrane     

Salinity Stress and the Content of Proline in Roots of Pisum sativum and Tamarix tetragyna

Amino acid composition of the free amino acid pool and the TCA-insolubleprotein fraction were investigated in root tips of pea and Tamarixtetragyna plants grown at various levels of NaCl salinity. Salinitystress induced an increase of proline content, mainly in thefree amino acid pool in both plants, and of proline or hydroxyprolinecontent in the protein. Externally-supplied proline was absorbedand incorporated into protein, by pea roots, more effectivelythan by Tamarix roots. Salinity stress, apparently, stimulatedthe metabolism of externally-supplied labelled proline. Pearoots have a very large pool of free glutamic acid; however,70 per cent of the ¹⁴C from externally-supplied ¹⁴C-U-glutamicacid was released as CO₂. Very small amounts of it were incorporatedinto protein. No measurable amount of radioactivity could bedetected in any one of the individual amino acids, either ofprotein hydrolysate or the free amino acid pool. Proline very effectively counteracted the inhibitory effectof NaCl on pea seed germination and root growth. A similar effectbut to a lesser degree was achieved with phenylalanine and asparticacid. The feasibility of proline being a cytoplasmic osmoticumis discussed.     

A Cryomicroscopic Study of Cylindrocystis brebissonii De Bary and Two Species of Micrasterias Ralfs (Conjugatophyceae, Chiorophyta) during Freezing and Thawing

The changes in morphology of the unicellular algae Cylindrocystisbrebissonii and two species of Micrasterias during freezingand thawing were observed on a light microscope fitted witha temperature controlled stage. At slow rates of cooling extensiveshrinkage of the protoplast was observed. The response of thecell wall varied with cell-type. In C. brebissonii plasmolysiswas not observed and the cell wall and protoplast shrank together.In Micrasterias the cell wall did not contract and a distinctplasmolysis was observed. Following freezing to and thawingfrom –25?C cells of C. brebissonii were non-viable butremained osmotically responsive. Cooling at faster rates inducedintracellular ice formation in all cell-types. The criticalrate of cooling varied with cell-type and was determined bycell volume and suface area. Intracellular gas bubbles wereobserved during thawing following both rapid and slow cooling. Following cooling in dimethylsulphoxide cells of C. brebissoniiwere protected against freezing injury. The recovery on thawingfrom –196?C being determined by the rate of cooling, anoptimum rate of 1?C min^–1 was observed. During slow ratesof cooling (<2?C min^–1) cells remained unshrunken,at faster rates (10?C min^–1) the loss of cell viabilitywas related to osmotic shrinkage during cooling rather thanto nucleation of intracellular ice. Intracellular ice formationwas observed only following significantly faster rates of cooling(>20?C min^–1). Key words: Cylindrocystis, Micrasterias, cryomicroscopy, freezing injury     

Effects of temperature, salinity and food level on the life history traits of the marine rotifer Synchaera cecilia valentina, n. subsp.

A strain of the marine rotifer Synchaeta cecilia valentina,n. subsp., isolated from the Hondo of Elche Spanish Mediterraneancoastal lagoon at 22 salinity, was cultured in the laboratoryin 20 ml test tubes and fed with the alga Tetrasemis suecica.The effect of two temperatures (20 and 24°C), four salinities(20,25,30 and 37) and two food levels (15 000 and 25000 cellsml^–1) on the life history traits of this rotifer werestudied in life tables performed with replicated individualcultures. Temperature and salinity had a significant negativeeffect (P < 0.001) on the average lifespan (LS) and on thenumber of offspring per female (R₀) The effect of food levelon LS is unclear, whereas R₀ is greater at 20°C with thelower concentration of algae and at 24°C with the higheralgal concentration. The maximum values of LS and R₀, 5.6 daysand 9.2 offspring per female, respectively, were recorded at20°C, 25o salinity and low food concentration. There isalso a clear negative effect on the intrinsic growth rate (r)due to salinity. The effect of temperature depends on the foodlevel and, as occurs with R₀ the maximum values of r occur withthe lower algal concentration at 20°C, whereas at 24°Cthey are obtained with the higher algal concentration. Theser values, from 1.04 to 1.10 day^–1, were reached at 24°C,salinities of 20–25 and with high food concentration.     

Changes in the growth rates of saline-lake diatoms in response to variation in salinity, brine type and nitrogen form

The growth rates of four saline-lake diatom taxa were measuredunder varying conditions of salinity (5, 8 and 11), brine type(sulfate- versus bicarbonate-dominated) and nitrogen form (NH₄⁺versus NO₃^–), using a full factorial design. With NO₃^–as the nitrogen source, Cyclotella quillensis, Cymbella pusillaand Anomoeoneis costata exhibited lower growth rates in thesulfate versus bicarbonate media. The strain of Chaetoceroselmorei used in these experiments, isolated from a sulfate-dominatedlake, was unable to grow on NO₃^– alone. In the NH₄⁺ treatments,neither salinity nor brine type affected the growth rates ofC.quillensis or C.elmorei. When supplied with NH₄⁺, C.pusillaand A.costata had higher growth rates in the bicarbonate versussulfate media, although for C.pusilla the difference on NH₄⁺was not as great as on NO₃^–. The impact of brine typeon NO₃^– use is consistent with the theory that sulfateinhibits molybdate uptake, as molybdenum is required for NO₃^–use but not NH₄⁺. Cymbella pusilla was the only taxon affectedby changes in salinity. The four taxa used in these experimentsare frequently found in saline lakes and saline-lake sediments,hence they are used in paleoclimate reconstructions; the resultspresented here provide additional information that may enhancethese diatom-based reconstructions.     

Effects of growth medium, temperature, salinity and seawater source on the growth of Gymnodinium catenatum (Dinophyceae) from Bahia Concepcion, Gulf of California, Mexico

Laboratory studies were performed to determine the effect oftemperature, salinity, seawater sources and culture media onthe vegetative growth of clonal cultures of Gymnodinium catenatumisolated from Bahía Concepción, Mexico. Theseisolates were heterothallic and isogamous. Exponential growthrates of G. catenatum in f/2 with different selenium concentrationsand soil extract and GSe media were moderate. Maximum cell yieldswere obtained in GSe and f/2 media with selenium (10^–8and 10^–7 M), while in f/2 medium with soil extract cellyields were considerably lower. The highest percentage of longchains was found in f/2 media supplied with selenium (10^–8M). The optimal temperature range for growth was 11.5–30°C,with the highest growth rates between 21 and 29°C. The rangeof salinity tolerated by G. catenatum changed with seawatersource. With seawater from Vineyard Sound (Massachusetts, USA),G. catenatum grew at salinities from 15 to 36, with an optimalgrowth rate obtained at salinities between 26 and 30. With seawaterfrom Bahía Concepción, this species toleratedsalinities from 25 to 40, with optimal growth at salinitiesbetween 28 and 38. Ecophysiological measurements reported hereare consistent with the environment of the bay, which has limitedinput of humic materials from runoff and high salinity and temperature.These data, when viewed with data from studies of globally distributedG. catenatum, demonstrate the ability of this species to livein a broad array of habitats.     

Growth and Osmoregulation of Chaetoceros muelleri in Relation to Salinity

The growth and osmoregulation of Chaetoceros muelleri Lemmermann(Bacillariophyceae) were investigated as a function of salinity.This centric diatom grew well over a wide range of salinityand required concentrations of NaCl above 10 mM for growth.Using gas chromatography- mass spectroscopy (GC-MS) analysisof cell extracts, we demonstrated that the alga contains anisomer of cyclohexanetetrol. The level of this isomer increasedwith increasing salinity. Levels of free amino acids also increasedwith increasing salinity, and quantitative determination withan amino acid analyzer revealed that the level of glutamic acidincreased the most with increases in salinity. Levels of intracellularK⁺ and Cl^– also increased significantly with increasesin salinity. Thus, in C. muelleri, not only organic solutessuch as the cyclohexanetetrol isomer and glutamic acid, butalso inorganic solutes such as K⁺ and Cl^– contribute toosmoregulation. (Received November 7, 1994; Accepted April 10, 1995)     

The life history of Pyramimonas amylifera Conrad (Prasinophyceae)

Several possible life history stages of a clone of Pyramimonasamylifera Conrad (Prasinophyceae) have been encountered in culturestudies. These include: 1) octoflagellates; 2) cysts; 3) quadriflagellates;4) biflagellates; and 5) multilobate cells with each lobe bearingeight flagella. The octoflagellates have the ultra-structuralcharacteristics previously documented for P. amylifera. Scanningelectron microscopy was used to examine surfaces of cysts andbiflagellates. Scales of the type which form the middle (basket-shaped)and outer (coronate) scale layers on the octoflagellate wereobserved on the surface of cysts. Scales of the type which formthe middle body layer on octoflagellates were observed on thebodies of biflagellates. Biflagellates, quadriflagellates, andempty cysts were observed in several cultures which had beensubjected to a 5-week dark incubation before return to a low-lightregime. In one of those cultures, a single cyst containing motileswarmers was observed. The biflagellates or quadriflagellatesmay represent cyst-germination products. ^*Present address: Department of Biology, University of SouthFlorida, Tampa, Florida, U.S.A. 33620.     

Seasonal and fine-scale spatial variations in egg production and triacylglycerol content of the copepod Acartia tonsa in a river-dominated estuary and its coastal plume

We measured egg production rates of the estuarine calanoid copepodAcartia tonsa in Mobile Bay, an estuary in the northern Gulfof Mexico. Two stations were sampled approximately monthly,one at the mouth of the bay and the other just beyond the mouthin the salinity front between bay and coastal waters. Over thewhole year, temperature was the most important environmentalvariable controlling egg production. Rates increased with temperatureup to 30°C and 140 eggs female^–1 day^–1. We foundno evidence of food limitation. There was no correlation betweenegg production and phytoplankton abundance, nor increased eggproduction in response to supplements of phytoplankton addedto natural food, suggesting that non-phytoplankton food wasimportant in the diet. At the highest egg production rates,the amount of the storage lipid triacylglycerol (TAG) in adultfemales was greatly diminished, to <50 ng female^–1.This suggests that lipids in the diet can be very tightly coupledto egg production. Both egg production and TAG content of femalesshowed significant variability on spatial scales of 3–15km, especially in relation to the salinity front separat ingwater outwelling from the bay from open coastal water. For organismsthat are using copepods and their eggs as food, this variabilitywould result in a heterogeneous food environment, both in termsof the abundance of food and its nutritional content.     

Effects of temperature and salinity on the growth of the red tide flagellates Heterocapsa circularisquama (Dinophyceae) and Chattonella verruculosa (Raphidophyceae)

Growth responses of the red tide flagellates, Heterocapsa circularisquama(Dinophyceae) and Chattonella verruculosa (Raphidophyceae),were examined with 36 different combinations of temperature(5–30°C) and salinity (10–35 PSU). Heterocapsacircularisquama did not grow at or below a temperature of 10°C.The maximum growth rate of H.circularisquama (1.3 divisionsday^–1) was obtained with a combination of 30°C and30 PSU. In contrast, C. verruculosa did not grow at 10 PSU andat temperatures of 25°C or more. The maximum growth rateof C. verruculosa (1.74 divisions day^–1) was obtainedwith a combination of 15°C and 25 PSU. A significant temperature-salinityinteraction on growth was found by factorial analysis. Basedon the physiological characteristics obtained in the presentstudy, these novel flagellates have a potential for future outbreaksof red tides in pre viously unaffected waters.     

REPRODUCTIVE CYCLE AND FECUNDITY OF THE DATE MUSSEL LITHOPHAGA LITHOPHAGA (BIVALVIA: MYTILIDAE)

The reproductive cycle and fecundity of the date mussel Lithophagalithophaga, L. a well-known, ediblespecies has been examined.Sexes are separate and the mean number of eggs per each gonadis 1.894 x 10⁶ ± 1.044 x 10⁶ S.D. Reproduction firstoccurs at an age of 2⁺years and at a shell length greater than0.9 cm. Gonad activity is annual and is observed at all ages.The sex ratio for individuals up to 7 cm is 3:1 in favour ofthe males, whereas it becomes 1:1 for individuals greater than7 cm. The release of gametes by males and females occurs almostsimultaneously and begins immediately after a decline in thehighest water temperature ( 27°C), an increase in salinity(>31) and a decrease in the dissolved oxygen (6.5 ppm). Smallpercentages of mature individuals appear during the first wintermonths thus lengthening the reproductive period. This phenomenonis attributed to the temperature difference in deeper waters,the delay in gamete release by young individuals, tide, waveaction and changes in salinity. The fecundity of Lithophagalithophaga is high because its life-cycle is adversely affectedby environmental factors such as waves and tides. Fecundityincreases with shell length, more so with total wet weight andmainly with the age of the animals. Summer seems to be the suitableseason to exploit the date mussel of shell lengths > 5 cm. (Received 6 September 1993; accepted 10 March 1994)     

Ecotypic Variation in the Osmotic Responses of Enteromorpha intestinalis (L.) Link.

Young, A. J., Collins, J. C. and Russell, G. 1987. Ecotypicvariation in the osmotic responses of Enteromorpha intestinalis(L.) Link.—J. exp. Bot. 38: 1309–1324. The physiological basis for salt tolerance has been studiedin the euryhaline marine alga Enteromorpha intestinalis. Adaptationto dilute and concentrated seawaters has been investigated inthree separate populations of this alga: marine, rock pool andestuarine. Internal K⁺, Na⁺ and Cl^– levels have been determined usingtracer efflux analyses. K⁺ has been shown to be the major osmoticsolute within this alga. Cellular levels of Cl^– and, inparticular, Na⁺ are low although levels in the cell wall arehigh. Levels of these ions varied considerably between the separateplants; K⁺ levels within marine plants of E. intestinalis aretwo to four times those found in the other populations. Thetertiary sulphonium compound ß-dimethylsulphonio-propionateis maintained at relatively high levels, although it remainsfairly insensitive to change in the external salinity. Changes in the tissue water content and cell volume are large,particularly within the estuarine plants. The thin cell wallsof these plants allow large changes in volume in the diluteconditions experienced in an estuary, while low turgor preventscell rupture. Thicker cell walls and small cells of the marineand rock pool plants assist in tolerating high and low externalosmotic potential—the estuarine plants respond poorlyto concentrated seawater. Key words: Enteromorpha, osmoregulation, ecotypes     

Ecology of the brine shrimp Artemia in the Yucatan, Mexico, Salterns

One year of field data on the Yucatan, Mexico, North Coast hypersalinepools and salterns revealed extreme alkalinity, salinity andtemperature conditions, hypoxia and in some instances, totaldesiccation. The four locations were similar in water temperature,nitrites, and phosphates, but differed in salinity, oxygen content,water depth, nitrates, ammonia, silicates, carbonates, sulfates,and pH. The dominant multicellular organism in these hypersalineecosystems is Artemia, the brine shrimp. Artemia abundance andpopulation dynamics were significantly correlated with specificenvironmental conditions, most often water temperature, salinity,and oxygen concentration. The different schedules of Artemiaand cyst production at each location suggest habitat partitioningamong the brine shrimp populations across the North Coast ofthe Yucatan Peninsula. Our results provide an ecological basisfor rational management of these endangered hypersaline ecosystems.     

The Effect of Temperature on Photosynthesis and Carbon Fluxes in Sunflower and Rape

Sunflower (Helianthus annuusL.) and oilseed rape (Brassica napusL.) were grown at constant temperatures of 30 ?C (warm) and13 ?C (cold). Maximal rates of photosynthesis between 5 ?C and35 ?C were at higher temperatures in sunflower than rape. Photosyntheticrate over 4 h at the growth temperature declined in warm-andcold-grown rape and cold-grown sunflower, but remained constantin warm-grown sunflower. The stimulation of photosynthesis by2.0 kPa O₂ compared to 21 kPa O₂ declined with decreasing temperature.At 10 ?C in warm-grown rape photosynthesis was insensitive to2.0 kPa O₂. However, sensitivity to low O₂ continued at 10 ?Cin warm-grown sunflower. Carbohydrates accumulated in the cold,particularly fructose, glucose and sucrose in warm-grown sunflowertransferred to 13 ?C. By monitoring changes of ¹⁴C in leaves after the assimilationof ¹⁴CO₂, the rates of carbon export from leaves, pool sizesand carbon fluxes between them were estimated. The transferof warm- and cold-grown rape to 13 ?C and 30 ?C, respectively,had little effect on these parameters over 22 h. However, exportof carbon from sunflower leaves at 13 ?C was markedly less thanat 30 ?C, irrespective of the growth temperature, due to slowerexport from the transport pool. The rapid suppression of carbonexport at 13 ?C in warm-grown sunflower may be due to inhibitedtranslocation rather than reduced sink demand in the cold. It is concluded that assimilate utilisation is more depressedin the cold than is photosynthesis; this imposes a greater restrictionon biomass production in sunflower than in rape. Key words: Sunflower, rape, temperature, photosynthesis, carbon fluxes     

Temperature and salinity effect on growth and chemical composition of Gyrodinium aureolum Hulburt in culture

A factorial experiment shows highly significant effects of temperature(12 5–22.5°C) and salinity (17.8–34 S) on thegrowth rate of Gyrodinium aureolum, with a significant temperature-salinityinteraction. The maximum growth rate of G aureolum is measuredto 0.61 div. day^–1 at 20°C and 22.3 S. Gyrodiniumaureolum does not grow at temperatures :10 °C or 25°Cand at salinities 12 S. The cellular content of carbon (C) andnitrogen (N) and the elemental ratios N/C, P/C and N/P are significantlyaffected by the temperature The cellular content of phosphorus(P) and the elemental ratios P/C and N/P vary significantlywith salinity Significant temperature-salinity interactionsare found for the cellular content of carbon, nitrogen and phosphorus.Variations in the N/P ratio indicate that G.aureolum has a largestorage capacity for phosphorus It is suggested that temperatureis one important limiting factor in the initiation of bloomsof G.aureolum in north European waters.