Effects of quantitative and qualitative variation in phenolic compounds on feeding in three species of marine invertebrate herbivores

The deterrent effects of brown algal phenolic compounds and the terrestrial polyphenolic tannic acid on feeding by three species of invertebrate herbivores from central California, including the gastropods Tegula funebralis (Adams) and Tegula brunnea (Phillipi) and the echinoid Strongylocentrotus purpuratus (Stimpson) were examined. Algal phenolics used were the monomeric phenolic phloroglucinol and polyphloroglucinols from Fucus vesiculosus (Linnaeus), Halidrys siliquosa (Linnaeus) Lyngbye and Eisenia arborea Areschoug. All of the polyphenolics deterred feeding by all three herbivores at concentrations of 5 mg · ml⁻¹ in agar disks. Concentrations of 2 mg · ml⁻¹ also generally deterred feeding by the gastropods (these levels were not tested against S. purpuratus). Relative amounts of deterrence by different compounds were similar, especially for the gastropods. Phloroglucinol deterred feeding by the echinoids, but not by T. funebralis. Responses of the echinoids were otherwise similar to the gastropods, but more variable. I also demonstrated deterrence of S. purpuratus by tannic acid using the “tanned” kelp technique of Steinberg (1985). Reactivity of the different phenolic compounds in the Folin-Denis procedure, a common colorimetric assay used to estimate levels of phenolics in plant tissue, was similar. This suggests that measuring phenolic levels in brown algae by this technique will not be greatly confounded by the occurrence of different kinds of phenolic molecules in different brown algae. This result, in combination with the similarity of the deterrent effects of the compounds used in this study, increases the validity of previous studies in the northeastern Pacific Ocean which correlate algal phenolic levels and diets or feeding preferences of invertebrate herbivores. For plants and herbivores in this region, this assay is a reasonable measure of a biologically meaningful phenomenon — levels of phenolic deterrents in the algae.     

Cochliopodium barki n. sp. (Rhizopoda, Himatismenida) re-isolated from soil 30 years after its initial description

A strain of Cochliopodium isolated from grassland soil at Sourhope Research Station (Scotland, UK) was found to be identical to the strain “Cochliopodium sp.2” studied by Bark in 1973. We name it Cochliopodium barki. It belongs to a group of species (comprising also C. minus and Cochliopodium sp. “NYS strain”) with very similar scale pattern.     

Impact of vitamin E supplement in standard laboratory animal diet on microvascular manifestation of ischemia/reperfusion injury

Aimed at improving animal fertility and health, diets for farm and laboratory animals have over the last few years been supplemented with increasing amounts of the antioxidant vitamin E. We now demonstrate by intravital microscopy that feeding hamsters with a vitamin E-supplemented “standard” rodent diet (60 ppm vitamin E) significantly reduces the microvascular manifestations of ischemia/reperfusion injury when compared to animals fed a nonsupplemented diet. Postischemic leukocyte adhesion to venular endothelium was reduced from 770 ± 204 cells/mm² at 24 h after reperfusion in control animals on the nonsupplemented diet to 403 ± 105 cells/mm² in animals on the “standard” rodent diet (means ± SD, N = 7 animals per group, p < 0.01). Animals on the nonsupplemented diet showed a dramatic loss of capillary perfusion density until 7 days after reperfusion (to 21 ± 13% of preischemic baseline values), whereas this loss was significantly attenuated (to 71 ± 12% of preischemic values, p < 0.01) in animals on the “standard” rodent diet. No difference in the extent of reperfusion injury was seen between animals on the “standard” rodent diet and animals on diets with substantially higher vitamin E supplements (300 ppm–30.000 ppm). Besides underscoring the benefit of vitamin E in reducing the extent of ischemia/reperfusion injury, this study raises the concern that vitamin E supplements in “standard” laboratory animal diets may have a far-reaching impact on biomedical research by jeopardizing established animal models of disease.     

Detectability and criterion measures in temporal generalization

Computer simulation of performance on “normal” and “episodic” temporal generalization tasks was used to examine the relations between the theoretical parameters of models which fit temporal generalization data (“timing sensitivity” and “threshold”), and the d′ (detectability) and beta (decision criterion) measures of signal-detection theory. In general, changes in timing sensitivity altered d′, whereas threshold changes affected beta, supporting the assertion that the two sorts of variables (“sensitivity/detectability” and “threshold/criterion”) were psychologically equivalent. Cases where temporal generalization gradients were apparently contaminated by “random responding” could be treated by changes in beta, but cases in which temporal generalization gradients were not peaked at the standard posed severe problems for a simple signal-detection account, although existing models of temporal generalization performance could deal with them.     

Contribution of response surface design to the development of glycerolysis systems catalyzed by commercial immobilized lipases

Two commercial immobilized lipases (“Lipozyme® IM” and “Novozym® 435”) were tested as biocatalysts for the glycerolysis of olive residue oil in n-hexane aimed at the production of monoglycerides (MG) and diglycerides (DG). A central composite rotatable design (CCRD) was followed to model and optimize glycerolysis as a function of both the amount of biocatalyst (L) and of the molar ratio glycerol/triglycerides (Gly/TG). For both biocatalysts, the production of free fatty acids (FFA) was described by second order models. In terms of MG and DG production, as well as of TG conversion, the best fits were obtained with first-order models. The highest MG productions were in the range 43–45% (w/w, on the basis of total fat) for both biocatalysts tested at a (Gly/TG) ratio of one. In the case of “Novozym 435”, the lowest load used (12%, w/w) gave the best results, in contrast with “Lipozyme IM” with which a concentration of about 26% (w/w) was necessary to obtain the highest production. Under these conditions, the amount of FFA produced was about 2% and 10% (w/w), respectively, for “Novozym 435” and “Lipozyme IM” catalyzed systems. Considering both FFA production and lipase loading, “Novozym 435” was shown to be a better biocatalyst for the glycerolysis of olive residue oil in n-hexane, aimed at the production of MG, than “Lipozyme IM”.     

Opsin biosynthesis and trans-cis isomerization of aldehyde form chromophore in the blowfly Calliphora erythrocephala eye

The effect of eye carotenoid content, light conditions and retinoid supply on the biosynthesis of opsin, as well as the ability to isomerize of exogenous all-trans-retinal to 11-cis-retinal were investigated in the photoreceptors of blowfly Calliphora. SDS-PAGE of digitonin extracts from isolated rhabdom fractions of carotenoid-fortified and carotenoid-deficient animals revealed, on heavily loaded gels, that in both cases opsin forms faint minor bands similar to the patterns of “R⁻-flies” described as “vitamin A-deficient flies” (Paulsen and Schwemer, Biochim. biophys Acta 557, 358–390, 1979) or “carotenoid-deficient flies” (Paulsen and Schwemer, Eur. J. Biochem. 137, 609–614, 1983. Similar opsin patterns were obtained in flies subjected to continuous 72 h blue or yellow-green light or to a 12 h: 12 h white light:dark cycle, or total darkness, irrespective of the carotenoid content in their eyes. 11-cis-retinal and, to a lesser extent, all-trans-retinal, when included in the diet or painted on the cornea, were found to stimulate opsin biosynthesis in the dark. 11-cis-retinal in the dark or all-trans-retinal after illumination of the flies with blue light were the most effective, as compared with the effect of all-trans-retinal in the dark. Exogenous all-trans-retinal in the dark can be partially converted into a mixture of 11-cis-retinal (26%) and 13-cis-retinal (74%) by fly retina homogenate in vitro. It was concluded that Calliphora opsin biosynthesis is not strongly dependent on the carotenoid supply or on light: dark conditions and is triggered by the 11-cis aldehyde form of the chromophore, which can be produced in the fly retina either by an isomerase system in the dark or as a result of photoisomerization.     

Systematic implications of the sesquiterpene lactones in the “strumarium” morphological complex (Xanthium strumarium, Asteraceae) of Europe, Asia and Africa

In most populations of the “strumarium” morphological complex of Xanthium strumarium L. (sensu lato) in northern Europe and in India, a new compound, xanthinosin, is the only detectable sesquiterpene lactone. In populations of this morphological complex in Portugal and Egypt as well as in eastern Asia, USSR, Korea, Hong Kong and Taiwan, xanthinin and xanthatin occur as major constituents along with xanthinosin. Experimental F, hybrids between pistillate Indian plants which contained only xanthinosin and staminate plants from Hong Kong which contained a mixture of xanthinin, xanthatin and xanthinosin produced a mixture of compounds in which the percentage of xanthinin increased relative to its percentage in the Hong Kong parent. The sesquiterpenoid data suggest that the various taxa in the “strumarium” morphological complex can be divided into three groups: (a) X. strumarium (sensu stricto) and X. indicum König, containing primarily or exclusively xanthinosin; (b) X. sibiricum Patrin and X. brasilicum Vell., with xanthinin and xanthinosin predominating; and (c) X. inaequilaterum DC., with almost equal proportions of xanthinin, xanthatin and xanthinosin. Two other taxa of the complex. X. japonicum Widd. and X. abyssinicum Wallr., were not available for inclusion in the present study.     

Modelling the microenvironment of a lipase immobilized in polyurethane foams

The effects of partition of substrates and product on the modelling of the microenvironment of an immobilized lipase were evaluated using Response Surface Methodology. The esterification of butyric acid with ethanol in n-hexane, catalyzed by Candida rugosa lipase immobilized in two biocompatible and relatively hydrophilic polyurethane foams (“Hypol FHP 2002™” and “Hypol FHP 5000™”) was used as the model system. For each set of initial conditions, the final concentration of substrates and ethyl butyrate in the microenvironment, at equilibrium, Cmicro, were estimated by mass balancing bulk and foams. The Cmicro values obtained were used to estimate the corresponding partition coefficients of ethanol (P_EtOH), butyric acid (P_BA) and ester (P_EB), between the foams (microenvironment) and the bulk medium. Foams containing previously inactivated lipase, as well as lipase-free foams were used. For both substrates, Cmicro values were, in the majority of the experiments, higher than their macroenvironmental counterparts. The lowest Cmicro values were observed with the less hydrophilic foam (“FHP 5000”). A decrease of Cmicro_EtOH in both foams and Cmicro_BA in “FHP 5000” foams, was obtained upon lipase immobilization. P_EB values were, in all cases, close to zero. This is beneficial in terms of the shift in reaction equilibrium, product recovery and alleviation of product inhibition effects.     

Tissue fatty acid deposition is influenced by an interaction of dietary oil source and energy intake level in rats

To investigate the net tissue fatty acid deposition in response to graded levels of energy restriction and modification of diet fatty acid composition, rats were randomly assigned into four dietary groups and fed for 10 weeks diets containing 40% as energy of either fish, safflower, or olive oil, or beef tallow, consumed ad libitum or energy restricted to 85% or 68% of ad libitum intake by reducing diet carbohydrate content. An additional eight rats were killed before the diet regimen, to provide baseline data from which fatty acid deposition rates were calculated. Body weight, and heart, liver and fat mass gains were decreased with energy restriction (P<0.001). Olive oil feeding resulted in higher body weight gain (P < 0.03) than tallow feeding, whereas fish oil feeding was associated with highest (P < 0.007) liver weight and lowest (P < 0.03) fat mass gains. Energy deficit-related differences in the deposition of stearic, linoleic, arachidonic, and docosahexaenoic acids in heart and palmitic and docosahexaenoic acids in liver were dependent on the dietary oil consumed (P < 0.03). Similarly, interactive effects of restricted food intake and dietary oil type were found in the gain of palmitic, stearic, oleic, and linoleic acids in adipose tissue (P < 0.01) when expressed in relation to the amount of each fatty acid consumed. These data suggest that energy intake level can influence the deposition pattern, as well as oxidation rate, of tissue fatty acids as a function of tissue type, fatty acid structure, and dietary fatty acid composition.     

Activation of chemical defenses in the tropical green algae Halimeda spp.

Halimeda spp. are among the most common seaweeds on tropical reefs where herbivory is intense. These calcified seaweeds produce diterpenoid feeding deterrents; the major metabolites are halimedatetraacetate and halimedatrial. We found that most species of Halimeda on Guam immediately convert the less-deterrent secondary metabolite halimedatetraacetate to the more potent feeding deterrent halimedatrial when plants are injured by grinding or crushing. This conversion would therefore occur when fishes bite or chew Halimeda plants. We term this process of rapid conversion “activation”. Extracts from injured plants contained higher amounts of halimedatrial and were more deterrent toward herbivorous fishes than extracts from control plants. Herbivore-activated defenses are common in many families of terrestrial plants: however, this is the first example of an activated defense in a marine plant.     

Earthworm-serine protease: characterization, molecular cloning, and application of the catalytic functions

An earthworm, Lumbricus rubellus, produces alkaline serine proteases that are greater than trypsins in their activity and stability. The proteases which were purified from the earthworm were composed of six isozyme proteins. Each isozyme consisted of a single polypeptide chain which was derived from the different genes. The enzymes had activity and were stable at below 60 °C over a wide range of pH 2–11 and were strongly resistant to organic solvents and detergents. Moreover, they retain full activity for long years at room temperature. They acted on various proteins, such as elastin as well as fibrin, and some peptides, such as β-amyloid 1–40 and solubilized actual fibrin clots of whole blood in a rat’s vena cava. They also catalyzed the hydrolysis of various esters. The cDNAs encoding the proteases were cloned and sequenced. They showed similarity to mammalian serine proteases and conserved the catalytic amino acid residues, however, neither arginine nor lysine residues were present in the autolysis region. The gene encoding the native form of an isozyme protein was expressed in Pichia pastoris to produce the active protease in the culture medium. The proteases contributed to the production of the “earthworm autolysate”. The extracts of the autolysate could be used as a “peptone substitute” in media for the efficient growth of microorganisms.     

Interactive effects of phenolic acid and nitrogen on morphological traits of poplar (Populus × euramericana ‘Neva’) fine roots

Aims The relationship between rhizosphere process and fine root growth is very close but still obscure. In poplar plantation, phenolic acid rhizodeposition and soil nutrient availability were considered as two dominant factors of forest productivity decline. It is very hard to separate them in the field and they might show an interactive effect on fine root growth. The objective of this study is to examine the influence of phenolic acids and nitrogen on branch orders of poplar fine roots and to give a deeper insight into how the ecological process on root-soil interface affected fine root growth as well as plantation productivity. Methods The cuttings of health annual poplar seedlings (I-107, Populus × euramericana ‘Neva’) serve as experiment materials, and were cultivated under nine conditions, including three concentration of phenolic acids at 0X, 0.5X, 1.0X (here, X represented the contents of phenolic acids in the soil of poplar plantation) and three concentration of nitrogen at 0 mmol·L^-1, 10 mmol·L^-1, 20 mmol·L^-1, based on Hoagland solution. The roots were all separated from poplar seedlings after 35 days, and 30 percent of total fine roots of every treatment were taken as fine root samples. These fine roots were grouped according to 1 to 5 branch orders, and then the morphological traits of each group of fine roots were scanned via root analyzer system (WinRHIZO, Regent Instruments Company, Quebec, Canada) including total length, surface area, volume and average diameter. Meanwhile, the dry mass of fine root samples of every order was measured to calculate specific root length (SRL), root tissue density (RTD). All data were analyzed via SPSS 17.0 software, and interactive effect of phenolic acids and nitrogen on roots was analyzed through univariate process module. Principal component analysis (PCA) and redundancy analysis (RDA) were conducted via Canoco 4.5 software. Important findings Under the conditions without phenolic acids application, the fine roots growth was significantly inhibited in deficiency and higher nitrogen treatments, especially for 1-3 order roots. Only specific root length appeared decreased with nitrogen level, and other traits of fine roots did not demonstrate linear relationship with nitrogen concentrations. Compared to 0.5X phenolic acids treatment, 1.0X phenolic acids significantly promoted the diameter and volume of 1-2 order roots (p < 0.05). Both phenolic acids and nitrogen demonstrated influence on poplar fine root traits. However, the diameter and volume of 1-2 order roots were significantly affected by phenolic acids, while the total length and surface area of 4-5 order roots was affected by nitrogen. Two way ANOVA showed that phenolic acids and nitrogen made a synergistic or antagonistic effect on morphological building of fine roots. Furthermore, PCA and RDA indicated that the interactive effects of phenolic acids and nitrogen led to significant differences among 1-3 order, 4th order and 5th order of poplar fine roots. The PC1 explained about 60.9 percent of root morphological variance, which was related to foraging traits of roots. The PC2 explained 25.3 percent of variance, which was related to root building properties. The response of poplar roots to phenolic acids and nitrogen was closely related to root order, and nitrogen played more influence on poplar roots than phenolic acids. Thus, phenolic acids and nitrogen level would affect many properties of root morphology and foraging in rhizosphere soil of poplar plantation. But nitrogen availability would serve as a dominant factor influencing root growth, and soil nutrient management should be critical to productivity maintenance of poplar plantation.     

Continuous cider fermentation with co-immobilized yeast and Leuconostoc oenos cells

Ca-alginate matrix was used to co-immobilize Saccharomyces bayanus and Leuconostoc oenos in one integrated biocatalytic system in order to perform simultaneously alcoholic and malo-lactic fermentation of apple juice to produce cider, in a continuous packed bed bioreactor. The continuous process permitted much faster fermentation compared with the traditional batch process. The flavor formation was also better controlled. By adjusting the flow rate of feeding substrate through the bioreactor, i.e. its residence time, it was possible to obtain either “soft” or “dry” cider. However, the profile of volatile compounds in the final product was modified comparatively to the batch process, especially for higher alcohols, isoamylacetate, and diacetyl. This modification is due to different physiology states of yeast in two processes. Nevertheless, the taste of cider was quite acceptable.     

酚酸和氮素交互作用下欧美杨107细根形态特征

树木细根生长与根际过程的关系十分密切。该研究仿生欧美杨107 (Populus × euramericana ‘Neva’)人工林根际土壤酚酸沉降与氮素有效性变化, 通过设置3种酚酸梯度(0X、0.5X、1.0X, X为田间土壤酚酸含量)与3种氮素水平(缺氮0 mmol·L^-1、正常氮10 mmol·L^-1、高氮20 mmol·L^-1), 探究酚酸和氮素对欧美杨107细根形态的影响, 以期为阐明树木根系生长对根-土界面过程的响应奠定基础。结果表明: (1)在无酚酸(0X)环境中, 缺氮和高氮均可抑制欧美杨107细根生长, 尤其对1-3级细根的影响更为显著。比根长随氮素水平升高逐渐减小, 但其他细根特征并未呈现与氮素水平的线性关系。(2) 0.5X和1.0X酚酸梯度相比, 欧美杨107的1-2级细根直径和体积随酚酸浓度增加而显著增大(p < 0.05)。酚酸和氮素对杨树细根的影响存在交互作用, 1-2级细根直径、体积受酚酸的影响显著, 而4-5级细根长度、表面积受氮素影响显著。双因素方差分析结果表明, 酚酸和氮素对细根形态建成具有协同或拮抗效应。(3)主成分分析(PCA)和冗余分析(RDA)结果表明, 在酚酸和氮素交互效应下, 杨树1-3级、 4级、 5级细根之间具有显著的形态差异。第一主成分主要体现细根觅食性状特征, 可解释细根形态变异的60.9%的信息; 第二主成分主要体现细根形态构建特征, 可解释25.3%的信息。杨树细根形态变化与根序高度相关, N素影响杨树细根形态的主效应较酚酸更强。因此, 根际环境中酚酸累积和氮素有效性变化会影响杨树细根的形态构建和细根对水分、养分的吸收, 而氮素有效性是影响杨树细根生长的重要因素, 开展杨树人工林土壤养分管理是林分生产力长期维持的关键。     

Responses of phenolic acid and defensive enzyme activities to mechanical damage in Artemisia frigida

Aims The study aims at understanding the effects of feed intake and trample damage on the phenolic acid formation and antioxidant enzyme activities in Artemisia frigida, and elucidating the adaptive mechanisms in A. frigida to grazing in secondary metabolites and their related enzyme activities.
Methods We analyzed the phenolic acid content and the activities of polyphenol oxidase (PPO), phenylalanine ammonia-lyase (PAL) and protective enzymes in leaves and roots in A. frigida under three levels (light, moderate, and heavy) of manipulative grazing condition. The measurements of the 9 phenolic acid contents started after 6 h of the mechanical damage of the plants by using the high performance liquid chromatography (HPLC), and the enzyme activities in leaves and roots were measured by a spectrophotometry method.
Important findings The light damage treatment induced productions of PPO, PAL and significantly (p < 0.05) increased antioxidant enzyme activities in the leaves and roots of A. frigida. The contents of PPO, PAL and antioxidant enzymes increased with increasing intensity of mechanical damage. Compared to the control, the content of free caffeic, syringic, ferulic and cinnamic acid in the leaves A. frigida were significantly elevated (p < 0.05) by 150.4%, 93.5%, 154.4% and 121.7%, respectively. They were significantly (p < 0.05) positively correlated with PAL activity in the moderate damage treatment. The content of free chlorogenic acid and catechol decreased by 91.1%, and 69.3%, respectively, compared with the control they had a negative correlation with PPO activity in the heavy damage treatment. The contents of gallic and protocatechuic acids increased (p < 0.05) by 280.6% and 215.7%, respectively, in the heavy damage treatment. With increasing intensity of mechanical damage, the content of 9 free phenolic acids significantly increased in roots but the increasing range was less than the one in leaves. Mechanical damage induced an increasing trend in the total amount of free and bounded phenolic acids in the leaves but a decreasing trend in the total amount of bounded phenolic acids in the roots of A. frigida. The results indicated that mechanical damage could firstly induce an increase of antioxidant enzymes and key enzymes in phenolic metabolism in A. frigida, leading to the accumulation of antioxidant substances of phenolic acids, further regulate the biosynthesis of lignins, quinones and tannins, and then enhance the resistance to mechanical damage and improved the tolerance of A. frigida to grazing.     

Enhanced condition in dogwhelks, Nucella lapillus (L.) living under mussel hummocks

Dogwhelks, Nucella lapillus eat both barnacles and mussels, Mytilus edulis. However, mussels are dangerous prey because they can snare and immobilize dogwhelks with their byssi. Despite this danger, adult dogwhelks are common inside mussel hummocks or stacks found on mature mussel beds. The whelks live in debris-filled chambers within the hummocks, unsnared by byssi. Evidence is presented to show that this is a highly favourable microhabitat for dogwhelks. Condition index (CI) measurements showed that mean CI for “hummock” dogwhelks was 20.99 in early spring, 29.65 in midsummer and 34.86 in early winter. In comparison, CI values for dogwhelks from nearby barnacle zones were 20.13, 25.03 and 24.66 respectively. The summer and winter CI values of “hummock” dogwhelks were enhanced to a highly significant extent. Data are also presented to show that shore elevation or dogwhelk shell height (over the size range of animals studied) had no confounding effect on this result. Predicted flesh and shell mass values for a standard 25 mm high whelk showed that occupation of hummocks was associated with a thin-walled shell morphology, and that the shell mass became proportionately lower in summer and early winter. A feeding experiment showed that CI rises slowly, even in dogwhelks fed to satiation on mussels. Dogwhelks were taken from the barnacle zone in March 1997 and either fed to satiation on Mytilus or starved, whilst being held in seawater at ambient seawater temperature. The CI of fed dogwhelks rose from 19.7 to 27.4 in 3 months, while that of starved Nucella fell from 19.7 to 16.3. In the meantime, the CI of dogwhelks in situ in the barnacle zone had risen from 19.7 to 23.8. Hence, 3 months' satiation ration had led to a nett 3.6 unit rise in CI; starvation to a nett 7.5 unit fall. All of the changes in CI were due to changes in flesh mass; shell mass was stable. Since “hummock” dogwhelks collected in early winter have a CI value about 10.2 units greater than barnacle zone dogwhelks, this indicates that “hummock” dogwhelks are long-term inhabitants of this microhabitat.     

Steroid metabolism by constitutive cytochromes P450

In rat liver endoplasmic reticulum some 16 different cytochromes P450 have been identified as constitutive, sequenced from recombinant DNA, and shown to be distinct gene products. These forms are “multipurpose”, i.e. functional in xenobiotic metabolism as well as endogenous substrate metabolism. In the latter case, these forms metabolize steroids, fatty acids, prostaglandins and even ketone bodies, indicating an involvement in homeostasis. In steroid metabolism, in contrast to “biosynthetic” forms of P450 which generally yield one product, the multipurpose forms exhibit broad, overlapping metabolite profiles, with isomeric and epimeric specificity and different mechanisms of product formation. The nature of the substrate docking region is of much interest and attempts have been made to rationalize the manner in which multiple metabolites are produced from a single substrate. Brain, with a very low level of P450 relative to liver also catalyzes steroid metabolism. The nature of the forms involved are not yet known.     

Zooplankton feeding ecology: bacterivory by metazoan microzooplankton

Bacterivory by the rotifer Brachionus plicatilis Müller, nauplii and copepodites of the copepods Centropages Krøyer sp. and Acartia tonsa Dana, and the tintinnid Favella panamensis Kofoid & Campbell was examined using fluorescently labelled bacteria (FLB) and epifluorescence microscopy. FLB were < 1 μm in diameter, and were offered at environmental concentrations (1.47−9.08 × 10⁶ cells·ml⁻¹). FLB were visible within rotifers, nauplii, copepodites, and tintinnids, confirming ingestion. Rotifer clearance rates (32–418 μl·animal⁻¹·h⁻¹) exhibited no relation with FLB concentration. In some cases rates of clearance of FLB by rotifers were different with alternative phytoplankton food (Nanochloris Naumann sp.) than in replicates with FLB alone, whereas in other cases presence of alternative food exhibited no clear effects on rates of ingestion of FLB. Clearance rates for all six naupliar stages of A. tonsa nauplii (0–320 μl·animal⁻¹·h⁻¹) were stage-related, with higher rates by NIII-VI nauplii than NI-II nauplii. Nauplii had higher rates of clearance of FLB in the absence of alternative phytoplankton food (Isochrysis Parke sp.). Clearance rates of FLB by a single stage of Centropages sp. nauplii, A. tonsa CI copepodites and F. panamensis (each obtained at only a single food concentration of either 1.5 or 5.0 × 10⁶ cells·ml⁻¹) were within the range of 85–142 μl·animal⁻¹·h⁻¹. These ranges were similar to those of rotifers and A. tonsa nauplii. This is the first report of FLB ingestion by metazoan marine microzooplankton. Although rotifers and ciliates might be expected to ingest small particles such as FLB using ciliary induced feeding currents, the means by which nauplii and copepodites eat FLB is less clear. We propose that they may “eat” bacteria as they “drink” to osmoregulate.     

Responses of the Circadian Locomotor Activity Rhythm of Mus Booduga to Shifts in LD Schedules

The responses of the field mouse Mus booduga to shifts in schedules of LD cycles were monitored and the results were interpreted with the help of a PRC constructed for the same species. The results reveal that, M. booduga reentrained faster with a lesser number of transients after delay shifts than advance shifts, thus exhibiting “asymmetry effect.” A positive correlation was observed between the number of transients and the number of hours of shift. In most of the shifts, the sign of the transients (negative for delaying transients and positive for advancing transients) coincided with the direction of the shift. Interestingly, 11 and 12 h of advance shifting resulted in delaying transients. An 11-h advance shift can also be interpreted as a 13-h delay. Reentrainment through delaying transients is faster as compared to reentrainment through advancing transients. Thus, this animal might have taken a “shorter route,” as proved by the fact that an 11-h advance shift has evoked delaying transients. But a 13-h advance shift evoked only advancing transients. This prompts us to speculate that there may be a “phase jump” in M. booduga. Further, irrespective of whether L or D has been doubled in a 12-h shift, both evoked only delaying transients.