Feeding dynamics,nitrogen budgets,and ecosystem role of a desert stream omnivore,Agosia chrysogaster (Pisces: Cyprinidae)

Synopsis Feeding habits, diel periodicity and total daily ingestion, and nitrogen budgets of longfin dace (Agosia chrysogaster) were examined on two occasions when food quality, but not quantity, differed. Agosia chrysogaster was found to be an opportunistic omnivore, consuming primarily insects when the preferred taxon (baetid mayflies) was abundant in the environment, but consuming primarily algae when mayfly abundance was low. Ingestion provided a better measure of diel feeding periodicity than gut fullness; feeding was diurnal on both sample dates, but more markedly so when the primary food was algae. Mean nitrogen content of algal foods was low, and A. chrysogaster apparently compensated for this by increasing its daily ingestion rate when algae were the major food. A reduction in nitrogen content of food during digestion from 4–6% (of dry mass) to less than 1% (in feces) suggested a high assimilation efficiency for nitrogen (nitrogen assimilated/nitrogen consumed = 72–78%). Populations of this abundant and successful cyprinid in Sonoran Desert streams may play an important role in ecosystem nitrogen dynamics. Nitrogen stored in fish biomass comprised 3–6% of the total nitrogen stored in Sycamore Creek, and excretion of ammonia by the fish represented 5–10% of total nitrogen uptake by algae. Such rapid recycling of usable nitrogen to primary producers is significant in this nitrogen limited stream ecosystem.     

Nitrogen flow through a Brachionus/Chlorella mass culture system

A model of nitrogen flow is presented through the Brachionus plicatilis/Chlorella saccharophila mass (batch) culture system, from the initial input of inorganic nitrogen to the algal culture medium to the final production of rotifers, dissolved nitrogen and particulate nitrogen.A nitrogen budget was first formulated for B. plicatilis relating ingestion, excretion, egestion, somatic growth and reproductive growth. Measurements were made on rotifers from 20° and 10° cultures.The calculated model of nitrogen flow through the rotifer/algal batch culture system estimates the percentages of the original input nitrogen which will be incorporated into algal nitrogen, rotifer nitrogen and the particulate and dissolved nitrogen pools. It is suggested that the dissolved nitrogen pool could be recycled directly for use in subsequent algal culture.     

The fate of Corydalis cava elaiosomes within an ant colony of Myrmica rubra: elaiosomes are preferentially fed to larvae

Summary. The diaspores of many plant species are adapted to dispersal by ants (myrmecochory). The ants carry the diaspores into their nests where the appendages of the diaspores (elaiosomes) are consumed. Little is known, however, about the fate of diaspores in the colony, i.e., whether elaiosomes are consumed only by the larvae or also by the workers. In this study, the distribution of Corydalis cava (Fumariaceae) elaiosomes was monitored between the larvae and the working caste of laboratory colonies of Myrmica rubra (Formicidae, Myrmicinae). In the first part of the study, ¹⁵N labelled elaiosomes were found to be mainly consumed by larvae. To find out whether elaiosomes are a more attractive food source than an artificial, nutritionally optimized diet for ants (Bhatkar diet), a combined ¹³C and ¹⁵N labelling experiment was conducted. Ants were offered ¹⁵N labelled elaiosomes for two days (pulse labelling), while being continuously fed with ¹³C labelled Bhatkar diet over 19 days. Under the given laboratory conditions, elaiosomes proved to be a far more attractive diet for the larvae than Bhatkar diet, contributing 87 ± 2% of the daily nitrogen and 79 ± 3% of daily carbon incorporation of larvae during the first four days of the experiment. The mean elaiosome incorporation met 73 ± 5% of nitrogen and 63 ± 6% of carbon demand of workers during the first four days of the experiment. Generally, incorporation rates in workers (per dry body mass) were lower both for carbon and nitrogen during the experiment – by a factor of 6.8 for nitrogen and by a factor of 6.2 for carbon compared to larvae. On a colony basis, workers received 39% and larvae 61% of the elaiosome nitrogen. The results indicate that elaiosomes are a major food source for growing larvae and thus support the hypothesis that elaiosomes play an important role in the life cycle of temperate ants.Received 22 December 2003; revised 16 June 2004; accepted 22 June 2004.     

Effect of dietary history and algal traits on feeding rate and food preference in the green sea urchin Strongylocentrotus droebachiensis

Feeding behaviour is influenced by a variety of factors, including nutritional requirements, the quality of available foods, and environmental conditions. We examined the effect of two factors, food morphology and dietary history, on the feeding rate and preference of the sea urchin Strongylocentrotus droebachiensis. Standardizing food shape and structure did not alter urchins' expected preference for the native kelp Laminaria longicruris over the invasive alga Codium fragile ssp. tomentosoides. However, when foods containing L. longicuris were shaped to mimic the algae, the C. fragile mimic was consumed more rapidly than the kelp mimic. Dietary history had no effect on single diet feeding rate. Urchins feeding on C. fragile consistently consumed twice as much (by mass) as those fed kelp, regardless of their previous diet. Despite higher feeding rates on C. fragile, urchins feeding on this alga were unable to compensate for its low energetic content and ingested less energy. Dietary history had a short-term effect on food preference, with urchins tending to prefer less familiar foods. Our findings suggest that urchins feed on C. fragile at a high rate, due to ease of handling and/or compensatory feeding, and that they do not a have strict preference hierarchy. Rather, food choice appears to reflect active maintenance of a mixed diet.     

Characterization of the bacterial flora of mass cultivated Brachionus plicatilis

Bacterial density and composition in association of mass cultivated rotifers (Brachionus plicatilis, SINTEF-strain) was investigated, during experimental conditions identical to the procedures used for preparing rotifers as live food for marine cold water fish larvae. These procedures include cultivation, enrichment with squid meal and acclimation to low temperature by storage of the rotifer culture at 6 °C. Large variations were observed in the number of rotifer associated (1.8–7.6 · 10³ colony forming units per rotifer^–1) and free-living (0.6–25 10⁷ cells·ml^–1) bacteria. An increase of 50–150% in the bacterial number was normally observed after feeding the rotifer with squid meal, but after three days of acclimation at 6 °C, the bacterial numbers decreased to the initial level.After enrichment of the cultures with squid meal, the similarity in the composition of the bacterial flora between the rotifers and water was reduced. However, acclimation of the culture at 6 °C resulted in better agreement of the rotifer associated flora and that in water. Enrichment of the cultures induced a shift in the bacterial composition from Cytophaga/Flavobacterium dominance to Pseudomonas/Alcaligenes dominance. The bacterial flora of the rotifer cultures are dominated by presumably opportunistic species after enrichment, which may have detrimental effects when rotifers are fed as live food to marine fish larvae.     

Axenic culture of <Emphasis Type="Italic">Brachionus plicatilis</Emphasis> using antibiotics

The rotifer Brachionus plicatilis culture is composed of complex microcosms including bacteria, protozoans, algae, and fungi. Previous studies reported methods to establish axenic rotifer cultures, but further refinement of these techniques is needed, for molecular biological research which requires pure culture to isolate nucleic acids from rotifers only. In order to render rotifer culture axenic, we tested five antibiotics: ampicillin (Amp), chloramphenicol (Cp), kanamycin (Km), nalidixic acid (Na), and streptomycin (Sm) at 30–100 μg/ml. Except for Cp, which reduces rotifer reproduction, all other antibiotics at the tested concentrations did not affect rotifer reproduction or show any toxic effects. A rotifer disinfection method was finally established by treating the resting eggs with 0.25% (w/v) sodium hypochlorite (NaOCl) for 3 min, washing with sterilized sea water, and then exposing the neonates to an Amp, Km, Na, and Sm mixture. Using four nutrient media, we confirmed that this protocol renders the rotifer culture bacterial and fungus free. The axenic rotifer culture generated here is useful not only for genetic analysis of Brachionus plicatilis, but for studying the rotifer life cycle without bacterial influence.     

Stimulation or inhibition of growth of the unicellular alga Pavlova lutheri by bacteria isolated from larval turbot culture systems

During growth of larval turbot in aquaculture the first food supplied is usually the rotifer, Brachionus plicatilis and algae are commonly included in the system as food for the rotifers, thereby maintaining their nutrient quality. As bacteria are known to influence markedly the survival of larval turbot, the effect of bacteria, isolated from larval turbot, on growth of Pavlova lutheri was measured over a 3-d period. Of 41 bacteria tested, 23 inhibited growth to various degrees, eight had no effect and 10 were weak growth stimulants. Four bacteria, identified as a Flavobacterium, Vibrio fluvialis, Vibrio natrigens and a Vibrio sp., were strongly inhibitory and the Flavobacterium inhibited growth of Pavlova lutheri from an inoculum of 10³ colony-forming units per ml. Inhibition was due to a heat-labile factor released by the Flavobacterium into the culture medium. The Flavobacterium also produced bacteriocin(s) which inhibited the growth of a range of vibrios. Bacteria antagonistic towards algae would be undesirable in larval rearing and if bacteria are to be selected which are beneficial (probiotics) in larval rearing systems their possible interaction with algae must be considered.     

Steady-state rotifer growth in a two-stage, computer-controlled turbidostat

Steady-state populations of rotifers (Brachionus calyciflorus)were maintained in twostage, continuous-flow turbidostatic cultureon the green alga Chlorella pyrenoidosa. In this system, themaximum specific growth rate,µ^max of the rotifers wasmaintained by using a computer to control the concentrationof algae, as rotifer food, in the rotifer culture. As rotifersconsumed algae, the turbidity decreased until a set-point wasreached. Then fresh algal suspension (supplied from a steady-statealgal chemostat) was metered into the rotifer culture, whichwas held in the dark. Rotifer and algal populations, as wellas rotifer µ^max entered steady states. These steady-stateresults were consistent with previous data from chemostat studies,but growth transients indicated that the of the µ^maxrotifersmay be subject to selection. The system is unique in providinga means to explore population dynamics of a metazoan maintainednear its µ^max.     

Modelling interactions between phytoplankton and bacteria under nutrient-regenerating conditions

The interactions of phytoplankton and bacteria in a nitrogen-limitedsteady-state system with an organic nitrogen compound or ammoniumas the sole nitrogen source were modelled. The effects of variousalgal excretion rates and two different mathematical representationsof excretion were examined. The model predicted that higherexcretion elevated the bacterial steady-state biomass, and loweredthe algal biomass. Bacterial respiration, which directly determinednitrogen regeneration, had an important effect on the system.The bacterial growth yield in the model was mainly a functionof the growth rate, and not of the nitrogen:carbon ratio ofthe substrate. In one version of the model, where the excretionof organic carbon increased with decreasing growth rate, themodel started to oscillate when the multiplication product ofmaximum specific excretion of excreted organic carbon (EOC)and the bacterial yield on EOC exceeded the dilution rate, irrespectiveof the form of nitrogen (ammonium or dissolved organic nitrogen)in the medium. The model results were compared with chemostatexperiments with the alga Emiliania huxleyi and a bacterialisolate in pure and mixed culture at two different dilutionrates. The carbon and nitrogen biomass of the bacteria was {smalltilde}1.5 times higher in mixed culture than in pure culture.In the experiments with low dilution rate, the recovery of nitrogenin the form of biomass, ammonium or amino acids was low, suggestingthe excretion by the algae of a refractory nitrogen-containingproduct which the bacteria could not use.     

Particle size dependent feeding by the rotifer Brachionus plicatilis

Size selective feeding by Brachionus plicatilis was investigated with algae and bacteria (0.3–3.5 µm) and mono-disperse latex beads (0.3–3.0 µm) in short term feeding experiments. B. plicatilis demonstrated maximum clearance rate of particles with diameter 2µm, but particles with diameter down to 0.3 µm were also ingested. The clearance rate of bacteria was 15–55% of that obtained for optimal sized particles (2 µm), and was related to particle size. The relative reduction in retention of particles with diameter < 2 µm was more pronounced for latex beads than for natural food particles, suggesting other mechanisms than size to be important for the particle retention by the rotifer. This is emphasized by the fact that the clearance rates were much lower for latex beads than for natural food particles of comparable size. Efficient retention of bacteria was observed for rotifers in poor physiological condition, i.e. rotifers with low maximum clearance rate. This may reflect a strategy to optimize energy utilization by reducing locomotion costs and increasing energy intake.The results indicate that B. plicatilis has a low to medium ability to feed on bacteria. In natural ecosystems, its importance as a bacterial grazer is of limited importance. At high population densities, such as in live feed cultures, the rotifer may, however, efficiently remove bacteria from the culture.     

Diet and activity budget of <Emphasis Type="Italic">Rhinopithecus roxellana</Emphasis> in the Qinling Mountains,China

We collected data on diet and daytime activity budget, and investigated the phenology of food trees and food abundance for a group of Rhinopithecus roxellana on the East Ridge of Yuhuangmiao in the Qinling Mountains from November 2001 to December 2003. We calculated the seasonal activity budget using data collected by scan sampling from 84 full-day observations (winter 16, spring 18, summer 28, autumn 22 days). During scan sampling we recorded behavioral states, and the food items and species consumed. The subjects consumed 84 plant species, including trees and shrubs of 29 families, and lichens. Food species varied seasonally. The overall diet of R. roxellana consisted of 29.4% fruit/seeds, 29.0% lichens, 24.0% leaves, 11.1% bark, 4.2% buds, 1.3% twigs and 1.0% unidentified items. Because the abundance of different food items varied seasonally, the monkeys had to shift their major food items seasonally. The annual activity budget of R. roxellana was 36.2% time spent resting, 35.8% feeding, 22.9% moving, and 5.1% other behavior. Seasonal changes in activity budget were observed. R. roxellana spent more time moving in autumn, when the quality of the food might be highest, and least time moving in winter when the food quality might be lowest. Thus, this type of monkey has a passive foraging strategy.     

Growth and food conversion of Brachionus rubens in continuous culture

The population fluctuations and dynamics of Brachionus rubenswere studied in a two-stage continuous culture system. The kineticsof the rates of filtration, ingestion and respiration were determinedand modelled. Growth potential, food conversion efficienciesand ammonia excretion rates of the rotifers were examined inorder to optimize the culture conditions of mass cultures. Monodkinetics and related mathematical concepts known from microbialchemostat cultures were successfully applied to the quasi-steadystates of the periodically diluted rotifer cultures. ^*Present address: Zoogesellschaft Osnabrück, Am Waldzoo,D-4500 Osnabrück, FRG     

Degradation of food compounds and growth response on different food quality by the anaerobic ciliate Trimyema compressum

The biochemical composition of two food bacteria was examined on which monoxenic cultures of Trimyema compressum grew with different yields. The food bacteria were the saccharolytic fermenting bacterium Bacteroides WoCb15 and the purple nonsulfur bacterium Rubrivivax gelatinosus. Differences in composition of bacterial biomass concerned mainly the carbohydrate content. By different culture conditions for R. gelationsus and pasteurization of carbohydrate-rich cells, we were able to feed the ciliate with food mixtures of different carbohydrate content. Dry mass yields of the ciliate reached a maximum with mixtures of 80% carbohydrate-rich pasteurized cells plus 20% carbohydratepoor living cells. In the absence of degradable carbohydrate, energy metabolism depended on protein as substrate. Utilization of protein was incomplete, large amounts were converted into soluble compounds that accumulated in the culture medium. The ciliate consumed storage carbohydrate of living or pasteurized food bacteria equally well, while growth with short generation times was still dependent on a certain percentage of living bacteria as source of native protein. Lipids, nucleic acids and denatured proteins were not degradable by the ciliate. Consequences for the fermentative metabolism of Trimyema compressum are discussed.     

栉孔扇贝生理生态学特征的实验研究

基于近年发展起来的生物沉积法,在烟台四十里湾养殖海区采用室内大型流水系统对栉孔扇贝的滤水率、吸收率和生态效率等生理生态学参数进行了测定,并探讨了它们与养殖密度与食物可获得性的关系．栉孔扇贝滤水率(平均3．65L·ind^-1·h^-1)与扇贝放养密度和饵料浓度无显著关系,而栉孔扇贝摄食率随放养密度的升高而降低,与POM呈正相关．扇贝对食物的吸收效率较高(平均75．9％),这与低饵料浓度行关．扇贝氨基酸泄漏所损失的能量高于排氨的能量损失．扇贝的生长余力(SFG)、总生长效率(尺：)和净生长效率(尺z)均与饵料浓度呈正相关．扇贝对氮的总生态效率(平均9．9％)高于对碳(平均5．9％)和磷(平均4．1％)．在氟的预算中,如果仅考虑NH4^ —N的排泄,而忽视其它形态氟的排泄,将会产生较大偏差(平均约20％)．贝壳不管在能量预算还是在元素预算中部不应该被忽视．在沿岸养殖海域,栉孔扇贝通过大量的滤水摄食、生长、排泄、生物沉积等对生态系统的能量流动和物质循环产生影响．     

Grazing on toxic and non-toxic Microcystis aeruginosa PCC7820 by Unio douglasiae and Corbicula fluminea

To explore the potential grazing effects of mussels on Microcystis aeruginosa, a common bloom-forming phytoplankton, Unio douglasiae and Corbicula fluminea were fed with Scenedesmus obliquus, toxic and non-toxic strains of Microcystis aeruginosa as single food and as mixtures in the laboratory. When fed with single foods, U. douglasiae has similar clearance rates on the three algae populations, while C. fluminea has significantly lower clearance rate on toxic M. aeruginosa than those on the other two algae populations. When fed with mixture foods, both the mussels show significantly higher clearance rates than on single foods. The clearance rates of U. douglasiae on the different food mixtures are not significantly different, and C. fluminea has a significantly lower clearance rate on the toxic food mixtures than that on non-toxic food mixtures. Although the relative lower clearance rates of C. fluminea on toxic food, we may still deduce that both the mussels can exert grazing pressure on phytoplankton. The deduction is supported by the composition of the excretion products. The excretion products (faeces and pseudofaeces) of both mussels contained mainly S. obliquus. In both mixed-food treatments, the ratios of S. obliquus to M. aeruginosa in the excrete products are significantly higher than those in the foods. Therefore, it can be concluded that both mussels prefer M. aeruginosa to S. obliquus, and can cause grazing pressure on M. aeruginosa.     

Studies on the incorporation of CO2 into starch by Chlorella vulgaris

Chlorella vulgaris was grown photosynthetically in batch culture under nitrogen sufficiency or nitrogen limitation. The starch content of the cells was measured as the amount of glucose released by enzymic hydrolysis of partially purified starch. Nitrogen sufficient algae contained approximately 20% of their dry weight as starch, whereas in nitrogen limited cells starch comprised up to 55% of the cellular dry weight. Starch production was pH dependent; optimal production of starch was achieved between pH 7.5 and 8.0. Optimal growth of C. vulgaris occurred at pH 7.0. Carbon yield experiments showed that for every gram of carbon consumed 0.5 g of starch (glucose) could be recovered. author for correspondence     

Linking herbivore-induced defences to population dynamics

1. Theoretical studies have shown that inducible defences have the potential to affect population stability and persistence in bi‐ and tritrophic food chains. Experimental studies on such effects of prey defence strategies on the dynamics of predator–prey systems are still rare. We performed replicated population dynamics experiments using the herbivorous rotifer Brachionus calyciflorus and four strains of closely related algae that show different defence responses to this herbivore. 2. We observed herbivore populations to fluctuate at a higher frequency when feeding on small undefended algae. During these fluctuations minimum rotifer densities remained sufficiently high to ensure population persistence in all the replicates. The initial growth of rotifer populations in this treatment coincided with a sharp drop in algal density. Such a suppression of algae by herbivores was not observed in the other treatments, where algae were larger due to induced or permanent defences. In these treatments we observed rotifer population densities to first rise and then decline. The herbivore went extinct in all replicates with large permanently defended algae. The frequency of herbivore extinctions was intermediate when algae had inducible defences. 3. A variety of alternative mechanisms could explain differential herbivore persistence in the different defence treatments. Our analysis showed the density and fraction of highly edible algal particles to better explain herbivore persistence and extinctions than total algal density, the fraction of highly inedible food particles or the accumulation of herbivore waste products or autotoxins. 4. We argue that the rotifers require a minimum fraction and density of edible food particles for maintenance and reproduction. We conjecture that induced defences in algae may thus favour larger zooplankton species such as Daphnia spp. that are less sensitive to shifts in their food size spectrum, relative to smaller zooplankton species, such as rotifers and in this way contributes to the structuring of planktonic communities.     

Dietary fat increases energy intake across the range of typical consumption in the United States

Objective: The fat content of a diet has been shown to affect total energy intake, but controlled feeding trials have only compared very high (40% of total calories) fat diets with very low (20% of total calories) fat diets. This study was designed to measure accurately the voluntary food and energy intake over a range of typical intake for dietary fat. Methods and Procedures: Twenty‐two non‐obese subjects were studied for 4 days on each of three diets, which included core foods designed to contain 26, 34, and 40% fat, respectively of total calories and ad lib buffet foods of similar fat content. All diets were matched for determinants of energy density except dietary fat. Subjects consumed two meals/day in an inpatient unit and were provided the third meal and snack foods while on each diet. All food provided and not eaten was measured by research staff. Results: Voluntary energy intake increased significantly as dietary fat content increased (P = 0.008). On the 26% dietary fat treatment, subjects consumed 23.8% dietary fat (core and ad lib foods combined) and 2,748 ± 741 kcal/day (mean ± s.d.); at 34% dietary fat, subjects consumed 32.7% fat and 2,983 ± 886 kcal/day; and at 40% dietary fat subjects consumed 38.1% fat and 3,018 ± 963 kcal/day. Discussion: These results show that energy intake increases as dietary fat content increases across the usual range of dietary fat consumed in the United States. Even small reductions in dietary fat could help in lowering total energy intake and reducing weight gain in the population.     

The role of the sea urchin,Tripneustes gratilla (Linnaeus), in decomposition and nutrient cycling in a tropical seagrass bed

The sea urchin,Tripneustes gratilla, which feeds mainly on living leaves of the seagrass,Thalassia hemprichii, was studied in its habitat on the southern coast of Papua New Guinea, and its roles in decomposition and nutrient cycling in a seagrass bed were assessed through the excretion of ammonium and metabolism of feces produced by the sea urchin. Carbon content of the fresh feces (21% of dry weight) was similar to that of intact dead leaves of the same species (22–23%). Carbon/nitrogen and carbon/phosphorus ratios of the feces (21.7 and 466, respectively), however, were significantly lower than those of the dead leaves (25.9–27.7 and 656–804, respectively), indicating that the feces retain more nitrogen and phosphorus in comparison with carbon. Net consumption of ammonium and orthophosphate typically concurred with oxygen consumption during dark incubation of both the dead leaves and the sea urchin feces. Compared with the same oxygen consumption rate, however, the dead leaves consumed more orthophosphate than the feces. Under sunlight, dead leaves showed a net accumulation of carbon by epiphytic algae, while the feces showed a carbon loss. Ammonium excretion by this sea urchin (1.7–5.4 mg nitrogen/individual/day) would thus appear to make a significant contribution to nitrogen recycling since biological communities associated with dead leaves and sea urchin feces tend to demand an external supply of nitrogen, such as ammonium.     

Modelling the influence of food C:N ratio, and respiration on growth and nitrogen excretion in marine zooplankton and bacteria

Zooplankton and bacteria use food to synthesize new biomassand meet respiratory demands. A steady-state bioenergetic modelis presented which explores the effects of the quality of assimilatedfood and respiration on growth and nitrogen excretion in marineheterotrophs. Processes of grazing and assimilation are notconsidered. Assimilated food is divided into two groups: nitrogenous(proteins) and non-nitrogenous (carbohydrates, lipids), andassumptions used to determine how each group is utilized forgrowth and respiration. Zooplankton growth is predicted to becarbon-limited, in contrast to existing experimental evidencewhich suggests nitrogen limitation. Excretion of nitrogen increaseswith the nitrogen content of food, and quantities of food consumed.A dissolved organic matter carbon to nitrogen ratio of 10.2:1was predicted below which bacteria remineralize nitrogen, andabove which ammonium is taken up from the environment and usedas a growth substrate. This compares well with experimentalstudies. The model provides valuable insight into the use ofsimpler nutrient-balancing models: critical assumptions aboutorganisms' carbon net growth efficiency must be made in orderto apply them successfully. In general, the study highlightedthe importance of having a proper understanding of respirationin marine organisms and how it is related to their biomass andgrowth.