Epidermal nutrition of the alcyonarian Heteroxenia fuscescens (Ehrb.): absorption of dissolved organic material and lost endogenous photosynthates

Summary The trophic strategies were studied of Heteroxenia fuscescens living in shallow tropical waters. Structural and physiological adaptations show that particulate food is of less nutritional importance than the uptake of organic material dissolved in the sea, the utilization of assimilates of cytosymbiotic algae (zooxanthellae) and even the symbionts themselves. The external and internal surfaces of the tentacles are enlarged by featherlike pinnules, on the one hand facilitating the epidermal uptake of dissolved organic compounds and on the other offering wellilluminated spaces in which large numbers of zooxanthellae can be cultivated.Zooxanthellae expelled from gastrodermal cells may be taken up by the mesenteric filaments of the dorsal mesenteries, where they are often decomposed and utilized. The transport of photo-assimilates from the gastrodermis to the epidermis through the mesogloea takes place at a low rate. Most of the released assimilates of the symbionts appear in the coelenteron. One fraction of these assimilates is distributed within the gastric channel system and can be taken up by developing stages living there; another fraction reaches the epidermis extracorporally via the pharynx and the sea. Thus both the pharynx and the epidermis absorb these photo-assimilates. The epidermal uptake capacity serves two main purposes: (1) active uptake and incorporation of external organic material dissolved in the sea; (2) reabsorption of internal, self-produced organic material, i.e. reduction of the loss of endogenous compounds escaping from the gastric cavity necessarily due to the polyfunctionality of the coelenteron.     

On feeding and nutrition in Fungiacava eilatensis (Bivalvia, Mytilidae), a commensal living in fungiid corals

The enlarged inhalant siphon of Fungiacava eilatensis opens into the coelenteron of species of fungiid corals with which it lives in commensal association. Material consisting of mucus, zooxanthellae, nematocysts, plankton and inorganic matter, is taken exclusively from the coelenteron. The very mobile foot possibly assists in food collection and in the removal of pseudofaeces; but, with large ctenidia, the bivalve is a typical ciliary feeder. Experiments with labelled zooxanthellae reveal that these are taken into the gut of Fungiacava with subsequent metabolic incorporation of products derived from them. The other prime source of food must be phytoplankton carried in with the feeding currents of the coral, itself carnivorous so that there is no competition for food between commensal and host. The Fungia zooxanthella– Fungiacava association operates as a "Troika" the productivity of which is autoregulated in proportion to the number of bivalves present. The inorganic wastes of the bivalve (as well as those of the coral) are utilized by the zooxanthellae, resultant increase in the algal component becoming available as food to the bivalve. Losses in the cycle are balanced by intake of exogenous food.     

Nutrition of the giant clam Tridacna gigas (L.). II. Relative contributions of filter-feeding and the ammonium-nitrogen acquired and recycled by symbiotic alga towards total nitrogen requirements for tissue growth and metabolism

We compare the relative contributions of filter-feeding and ammonium-nitrogen translocated from algal symbionts (zooxanthellae) towards the total nitrogen requirements for tissue growth and metabolism in the giant clam Tridacna gigas. Isotope enrichments suggest that zooxanthellae effected most if not all primary assimilation from high concentrations ( 15 μM) of ¹⁵N-ammonium. There was a net daily uptake of ammonium from natural seawater, which was modulated according to nutritional history, light history, ammonium concentration, and possible biological rhythmicity. Zooxanthellae also assimilated nitrogen excreted by host tissues, including ¹⁵N absorbed from ingested alga. Nearly 100% of the ¹⁵N subsequently released from zooxanthellae was incorporated in host tissues, with no significant loss from the clam over at least 10 days. Zooxanthellae therefore conserve and recycle essentially all nitrogenous end-products within T. gigas, affording giant clams a nutritional advantage over non-symbiotic bivalves. In further contrast with heterotrophic bivalves from particle-rich environments, T. gigas show longer gut passage times and high net and gross efficiencies (78.1 ± 9.4% and 99.2 ± 0.4%, respectively) with which organic nitrogen is absorbed from ingested particles. Filter-feeding and/or other non-autotrophic processes were essential as a source of nitrogen to maintain observed rates of juvenile growth, but declined in significance with increasing clam size. Even under cloudy conditions of limited irradiance, the total contribution of nitrogen acquired as ammonium by zooxanthellae exceeded the contribution from ingested particles in T. gigas larger than about 0.1 g, increasing to at least 45% of total nitrogen requirements in clams of 10 g. Ammonium-nitrogen translocated from zooxanthellae also satisfied all basal requirements for nitrogen in particle-starved clams larger than 0.1 g. Irrespective of size, ingested particles and ammonium-nitrogen acquired by zooxanthellae together supplied about 70% of the total observed nitrogen requirements. We stress the need to determine effects of irradiance on uptake of dissolved inorganic nitrogen, and to quantify dissolved organic matter as a potential additional significant source of nitrogen, that might further explain the high rates of growth in this clam species.     

Plasticity of the scleractinian body plan: Functional morphology and trophic specialization ofMycedium elephantotus (Pallas, 1766)

Summary Morphological, histological and behavioral features indicate thatMycedium elephantotus, a zooxanthellate scleractinian species without tentacles, is well adapted for utilizing suspended organic matter for nutrition. The colonies are composed of vertically growing fan-like plates and can reach diameters of more than 1 m in depths below 20 m. The external body surface is coated with a mucus layer (cuticle) which enables the acquisition and accumulation of suspended organic material. The mucus-entangled particles pass to the mouth openings by gravitational transport assisted by water movement. In experiments the corals were able to discriminate between suspended food and mineral particles. Both types of particles were rapidly entangled in fine mucus nets or filaments. Mineral particles were never ingested and instead tumbled down the inclined skeletal plates. In contrast, food particles were actively incorporated when the mucus filaments accidentally touched the stomodaea during the downward gliding. The food-enriched mucus filaments were either transported by ciliary activity into the coelenteron or were sucked into the body cavities by decreasing pressure in the coelenteron caused by contraction of longitudinal, mesenterial muscles. The discriminative reactions to mineral or food particles are probably based on the release of different types of mucus. Nematocysts are infrequent in the oral epidermis, indicating that the capture of living prey plays a subordinate role in nutrition. The mesenterial filaments, in contrast, are densely packed with large nematocysts. Storage products were piled up within the tissues of gastral pockets. The adaptations ofMycedium elephantotus for using suspended food particles may explain the particularly high abundance of this species between ca. 20 and 40 m depth on a steeply inclined fore-reef slope in the Gulf of Aqaba (Red Sea). The evidence indicating the importance of heterotrophic fueling toM. elephantotus is supported by carbonate production rates which are, in contrast to that of many other zooxanthellate scleractinian species, almost constant at depths between 5 and 40 m and which are uneffected by varying light regimes over the year, suggesting that the reduced phototrophic contribution by the zooxanthellae is compensated by mucus suspension feeding.     

Programmed cell death and cell necrosis activity during hyperthermic stress-induced bleaching of the symbiotic sea anemone Aiptasia sp.

Different cell death pathways were investigated during bleaching in the sea anemone Aiptasia sp. in response to hyperthermic treatment. Using a suite of techniques, (haematoxylin and eosin staining of paraffin wax-embedded tissue sections, in-situ end labelling (ISEL) of fragmented DNA, agarose gel electrophoresis electron microscopy) both necrotic and programmed cell death (PCD) activity were indicated. After a treatment period of 4 days, the host endoderm tissues underwent necrotic cell death. This was indicated by widespread cellular degradation, dilation of cell cytoplasm and organelles, cell swelling and rupture, irregular pyknotic condensation of nuclear chromatin, and abundant cell debris. Host cell necrosis was associated with the release of zooxanthellae with a normal, healthy appearance into the coelenteron. Longer periods of hyperthermic treatment (7 days) were correlated with further animal cell degradation and the in-situ degradation of zooxanthellae remaining within the degraded endoderm. Within the same degraded endoderm tissue, the degradation of zooxanthellae resulted from two forms of cell death occurring simultaneously, which were identified as programmed cell death and cell necrosis. Programmed cell death of zooxanthellae was characterised by condensation of the cytoplasm and organelles, cell shrinkage, formation of accumulation bodies at the periphery of the cell wall, and DNA fragmentation. Cell necrosis of zooxanthellae was characterised by dilation of the cytoplasm and organelles, cell swelling and lysis, dispersion of cell component debris, and DNA fragmentation. The existence of a programmed cell death pathway within zooxanthellae is important to the understanding of coral bleaching events, raising interesting questions regarding the evolution of this process and the activation of the cellular trigger mechanisms involved.     

The Medusa of Velella velella (Linnaeus, 1758) (Hydrozoa, Chondrophorae)

A mature medusa of Velella velella (Linnaeus, 1758) is reportedfor the first time from the North Atlantic; previously adultmedusae were known only from the Mediterranean. This specimen,collected by SCUBA divers, is the largest specimen recordedto date. Distinctive features are: two opposite adaxial-axialpairs of perradial capitate tentacles; two marginal bulbs lackingtentacles; conical manubrium with 4 perradial longitudinal gonads;perradial exumbrellar cnidae tracts; cnidome of stenoteles andmacrobasic euryteles; and zooxanthellae within the subumbrella.Since this specimen was collected near the surface and has zooxanthellae,it is likely that V. velella medusae are epipelagic.     

Heat stress stimulates nitric oxide production in Symbiodinium microadriaticum: a possible linkage between nitric oxide and the coral bleaching phenomenon

Nitric oxide (NO) is a gas displaying multiple physiologicalfunctions in plants, animals and bacteria. The enzymes nitratereductase and NO synthase have been suggested to be involvedin the production of NO in plants and algae, but the implicationof those enzymes in NO production under physiological conditionsremains obscure. Symbiodinium microadriaticum, commonly referredto as zooxanthellae, is a marine microalga commonly found insymbiotic association with a cnidarian host including reef-buildingcorals. Here we demonstrate NO production in zooxanthellae uponsupplementation of either sodium nitrite or L-arginine as asubstrate. The nitrite-dependent NO production was detectedelectrochemically and confirmed by the application of 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide(cPTIO), a specific NO scavenger. Cells stained with the diaminofluorescein,DAF-2 DA, an NO fluorescent probe, showed an increase in fluorescenceintensity upon supplementation of both sodium nitrite and L-arginine.Microscopic observations of DAF-stained cells verified thatNO was produced inside the cells. NO production in S. microadriaticumwas found to increase upon exposure of cells to an acute heatstress which also caused a decline in the photosynthetic efficiencyof PSII (F_v/F_m). This study provides substantial evidence toconfirm that zooxanthellae can synthesize NO even when theyare not in a symbiotic association with a coral host. The increasein NO production at high temperatures suggests that heat stressstimulates the microalgal NO production in a temperature-dependentmanner. The implications of these findings are discussed inthe light of the coral bleaching phenomenon which is associatedwith elevated sea surface temperature due to global warming.     

The Uptake of Growth Substances: XIV. PATTERNS OF UPTAKE BY LEMNA MINOR OF PHENOXYACETIC AND BENZOIC ACIDS FOLLOWING PROGRESSIVE CHLORINATION

The interrelationships between chemical structure and patternsof uptake by Lemna minor have been examined for (a) phenoxyaceticacid and its 2-, 4-, 2,4-, 2,6-, 3,5-, 2,5-, 2, 4, 5- and 2,4,6-chloroderivatives and (b) benzoic acid and its 2-, 2,4-, 2,5-, 2,3,6-chloro-and 3,6-dichloro-2-methoxy derivatives. All compounds contained¹⁴C in the carboxyl group. The plants from a clonal populationwere grown at a constant temperature and continuously illuminated. With progressive chlorination of phenoxyacetic acid, uptakeis enhanced, so that by 6 h there is a fourfold difference betweenthe monochloro- and trichloro-derivatives. In complete contrast,chlorination of benzoic acid greatly suppresses uptake and thedifferences associated with the degree of chlorination are smaller. Arising out of previous studies, the effects of adding streptomycin,synthalin, and cetyltri-methylammoniumbromide on the courseof uptake of individual members of the two series have beenexamined. Each of the additions can induce positive, negative,or null changes in the pattern of uptake, but the nature ofthe response is also dependent on the properties of the compound. These findings are discussed in relation to prior studies concerning(a) penetration into the leaves of Phaseolus vulgaris, (b) uptakeby excised segments of etiolated stems, and (c) changes in physico-chemicalproperties resulting from progressive chlorination. Many of the complexities still remain to be resolved but itseems clear that adsorption by Borne membrane system involvingthe carboxyl group of the entering acid and the positively chargedquaternary ammonium group of alpha-lecithin cannot be restrictedto compounds which are physiologically active as auxins or herbicides.     

Comparative mutant analysis of Arabidopsis ABCC-type ABC transporters: AtMRP2 contributes to detoxification, vacuolar organic anion transport and chlorophyll degradation

The enormous metabolic plasticity of plants allows detoxificationof many harmful compounds that are generated during biosyntheticprocesses or are present as biotic or abiotic toxins in theirenvironment. Derivatives of toxic compounds such as glutathioneconjugates are moved into the central vacuole via ATP-bindingcassette (ABC)-type transporters of the multidrug resistance-associatedprotein (MRP) subfamily. The Arabidopsis genome contains 15AtMRP isogenes, four of which (AtMRP1, 2, 11 and 12) clustertogether in one of two major phylogenetic clades. We isolatedT-DNA knockout alleles in all four highly homologous AtMRP genesof this clade and subjected them to physiological analysis toassess the function of each AtMRP of this group. None of thesingle atmrp mutants displayed visible phenotypes under controlconditions. In spite of the fact that AtMRP1 and AtMRP2 hadbeen described as efficient ATP-dependent organic anion transportersin heterologous expression experiments, the contribution ofthree of the AtMRP genes (1, 11 and 12) to detoxification ismarginal. Only knockouts in AtMRP2 exhibited a reduced sensitivitytowards 1-chloro-2,4-dinitrobenzene, but not towards other herbicides.AtMRP2 but not AtMRP1, 11 and 12 is involved in chlorophylldegradation since ethylene-treated rosettes of atmrp2 showedreduced senescence, and AtMRP2 expression is induced duringsenescence. This suggests that AtMRP2 is involved in vacuolartransport of chlorophyll catabolites. Vacuolar uptake studiesdemonstrated that transport of typical MRP substrates was reducedin atmrp2. We conclude that within clade I, only AtMRP2 contributessignificantly to overall organic anion pump activity in vivo.     

Dissolved Organic Matter as a Potential Source of Nutrition for Marine Organisms

The general features of accumulation of amino acids by marineinvertebrates are outlined. The wide distribution of this abilityis noted. Data from observations of this process for periodsof several days are presented for the polychaete worm, Doruilleaarticulata. Measurements of the constituents in the pool offree amino acids of this same organism are presented togetherwith data concerning the rate of appearance of radioactivityin the medium after permitting animals to accumulate amino acids.These data permit tentative estimates of rates at which aminoacids are lost to the medium. These apparent "leakage" ratesare low when compared with rates of uptake. The thermodynamicwork necessary to move material against the concentration differencesinvolved is calculated. The fraction of metabolic energy neededis small. The possible biological significance of uptake ofsmall organic compounds is discussed. It is concluded that uptakeof amino acids occurs sufficiently generally and at such ratesthat it should be included in any analysis of the pathways wherebymaterial is acquired from the environment by marine organisms.     

The Uptake of Growth Substances: V. VARIATION IN THE UPTAKE OF A SERIES OF CHLORINATED PHENOXYACETIC ACIDS BY STEM TISSUES4GOSSYPIUM HIRSUTUM AND ITS RELATIONSHIP TO DIFFERENCES IN AUXIN ACTIVITY

When segments excised from the etiolated hypocotyls of Gossypiumhirsutum are pretreated in buffer, the subsequent uptake ofradioactive 2,4-dichlorophenoxyacetic acid (2,4-D-1-¹⁴C) isdepressed and the net loss of radioactivity which normally followsa phase of positive uptake by freshly excised segments doesnot take place. Uptake by fresh segments, in contrast with uptakeafter pretreatment, has a high Q₁₀ and is markedly depressedby both 2,4,5-trichlorophenoxyacetic acid (2,4,5-T) and 3-indolylaceticacid. On these grounds it is proposed that net loss resultsfrom the release of material accumulated by a specific mechanismwhich, with time, becomes inoperative. Additional experimentssuggest that part of the 2,4-D taken up by stem segments ofTriticum vulgare and Avena sativa is accumulated by a similarmechanism. For 1-cm segments, entry is most rapid through the cut ends,and the effects of pretreatment exert their maximal effectsin the tissue near the ends. Therefore very short segments havebeen used to compare the courses of uptake of phenoxyaceticacid (POA) and its 2-, 4-, 2,6-, 2,4- and 2,4,5- chloro- derivatives.The patterns observed are similar to those previously reportedfor 1 -cm segments, although the differences between compoundsare greater. The courses of uptake of 2,4-D and 2,4,5-T, bothterminate in a phase when there is a net loss. POA and the 2-chloro-substitutedacid (2-CPA) are both continuously accumulated. No net lossis found with either the 2,6- (2,6-D) or the 4- chloro (4-CPA)compounds but the rates of uptake progressively decrease toa low level. It is proposed that the processes which determine the patternof uptake of chlorinated phenoxyacetic acids include two typesof accumulation. With Type I accumulation the mechanisms involvedrapidly become disorganized after tissues are excised from theplant. Type 2 accumulation, on the other hand, is stable. Theavailable data indicate that Type I accumulation is peculiarto compounds with marked auxin-like properties.     

The Application of Autoradiography to Developmental Studies in the Hydrozoa

The uptake of isotopically labelled nucleotides and amino acidshas been studied in five species of hydrozoans. In three speciesthe label was introduced both through immersion in a mediumcontaining the labeled compound and by injecting the labeledcompound into the gastrovascular cavity. In the remaining twospecies the label was introduced by immersion only. The comparisonof soaked and injected specimens clearly indicates that injectionis the method of choice whenever the injection of compoundsinto the gastrovascular cavity is possible. The relative easewith which labeled compounds were absorbed can be correlatedwith the ultrastructure of the epidermal and gastrodermal cellsurfaces and their associated extracellular coats. The use ofthese autoradiographic techniques is illustrated by the useof injected tritiated thymidine and tritiated uiidine to followthe replacement cycle of the zymogenic secretory cell in Hydra,and the use of immersion to introduce tritiated thymidine intothe planula larva of Pennaria.     

Characterization of regulatory mechanisms and states of human organic cation transporter 2

Polyspecific organic cation transporters (OCTs) have a large substrate binding pocket with different interaction domains. To determine whether OCT regulation is substrate specific, suitable fluorescent organic cations were selected by comparing their uptake in wild-type (WT) human embryonic kidney (HEK)-293 cells and in HEK-293 cells stably transfected with hOCT2. N-amidino-3,5-diamino-6-chloropyrazine-carboxamide (amiloride) and 4-[4-(dimethylamino)-styryl]-N-methylpyridinium (ASP) showed concentration-dependent uptake in hOCT2 at 37°C. After subtraction of unspecific uptake determined in WT at 37°C or in hOCT2 at 8°C saturable specific uptake of both substrates was measured. K_m values of hOCT2-mediated uptake of 95 µM amiloride and 24 µM ASP were calculated. Inhibition of amiloride and ASP uptake by several organic cations was also measured [IC₅₀ (in µM) for amiloride and ASP, respectively, tetraethylammonium (TEA) 98 and 30, cimetidine 14 and 26, and tetrapentylammonium (TPA) 7 and 2]. Amiloride and ASP uptake were significantly reduced by inhibition of Ca²⁺/CaM complex (–55 ± 5%, n = 10 and –63 ± 2%, n = 15, for amiloride and ASP, respectively) and stimulation of PKC (–54 ± 5%, n = 14, and –31 ± 6%, n = 26) and PKA (–16 ± 5%, n = 16, and –18 ± 4%, n = 40), and they were increased by inhibition of phosphatidylinositol 3-kinase (+28 ± 6%, n = 8, and +55 ± 17%, n = 16). Inhibition of Ca²⁺/CaM complex resulted in a significant decrease of V_max (160–99 photons/s) that can be explained in part by a reduction of the membrane-associated hOCT2 (–22 ± 6%, n = 9) as determined using FACScan flow cytometry. The data indicate that saturable transport by hOCT2 can be measured by the fluorescent substrates amiloride and ASP and that transport activity for both substrates is regulated similarly. Inhibition of the Ca²⁺/CaM complex causes changes in transport capacity via hOCT2 trafficking. organic cation transport; fluorescence measurement; 4-[4-(dimethylamino)-styryl]-n-methylpyridinium; amiloride     

INITIAL SETTLEMENT BEHAVIOUR AND SURVIVORSHIP OF LITHOPHAGA BISULCATA (d'ORBIGNY) (MYTILIDAE: LITHOPHAGINAE)

Although infaunal associates of living reef building coralsindude numerous phyla, initial settlement on the coral hosthas never been described. Experiments described here includedraising the larvae of a common Caribbean coral-boring mussel,Lithophaga bisulcata to observe their behaviour in the presenceof a variety of settlement substrates. On Stephanocoenia michelini,the most common host, larvae moved about the coral surface withimpunity, exploring the surface with the foot. On this coralspecies, competent pedi-veligers were ingested by the coralbut not necessarily digested. Penetration of the coral is initiatedby entering the coelenteron, where metamorphosis will presumablytake place. On species which L. bisulcata rarely inhabits, thelarvae appeared to be stung by nematocysts and withdrew thefoot rapidly from contact with the tissue Habitation of a living coral substrate appeared to be beneficialto the bivalve. Although L. bisulcata inhabits both riving anddead coral, there is evidence that survival, longevity and reproductiveoutput are enhanced when the mussel is surrounded by livingcoral tissue (Received 9 June 1987;     

Respiration and Mitochondrial Activity in Zea mays Roots As Affected by Osmotic Stress

Studies were made of metabolism in highly vacuolated and slightlyvacuolated Zea mays root tissue both during and after plasmolysis. Plasmolysis resulted in decreased respiration and carbon dioxideevolution from glucose and an increased sucrose synthesis. Inhibitionof respiration during plasmolysis in both the highly vacuolatedand slightly vacuolated tissue was not relieved by supply ofglucose, organic acids, or uncouplers of oxidative phosphorylation.Mitochondria isolated from plasmolysed tissue were tightly coupled,but activity in vitro was inhibited by exposure to a high negativeosmotic potential. It is suggested that low TCA cycle activityin vivo must be due either to inhibition of mitochondrial activityor to reduced flow of carbon through the glycolytic pathway. A low potential for TCA cycle activity after deplasmolysis issuggested, as addition of pyruvate stimulated carbon dioxideevolution but not oxygen uptake, which was severely decreased.This was presumably due to severe mitochondrial damage as shownby their activity in vitro. However, it is not clear whetherrespiration in vivo is rate limited by rapid leakage of metabolicintermediate (reported earlier) or by lysis of mitochondria. Deplasmolysis did not damage mitochondria from slightly vacuolatedtissue, a result which was consistent with respiratory measurementsmade in vivo. The data show that mitochondria in vacuolated tissue are damagedduring and after deplasmolysis and not before. It is suggestedthat lysis of mitochondria occurs in vivo as a result of a sharpincrease in the osmotic potential of the cell fluids.     

Role of thyroglobulin endocytic pathways in the control of thyroid hormone release

Thyroglobulin (Tg), the thyroid hormoneprecursor, is synthesized by thyrocytes and secreted into the colloid.Hormone release requires uptake of Tg by thyrocytes and degradation inlysosomes. This process must be precisely regulated. Tg uptake occursmainly by micropinocytosis, which can result from both fluid-phasepinocytosis and receptor-mediated endocytosis. Because Tg is highlyconcentrated in the colloid, fluid-phase pinocytosis or low-affinityreceptors should provide sufficient Tg uptake for hormone release;high-affinity receptors may serve to target Tg away from lysosomes,through recycling into the colloid or by transcytosis into thebloodstream. Several apical receptors have been suggested toplay roles in Tg uptake and intracellular trafficking. A thyroidasialoglycoprotein receptor may internalize and recycle immature formsof Tg back to the colloid, a function also attributed to an as yetunidentified N-acetylglucosamine receptor. Megalin mediatesTg uptake by thyrocytes, especially under intense thyroid-stimulatinghormone stimulation, resulting in transcytosis of Tg from the colloidto the bloodstream, a function that prevents excessive hormone release.

     

Sedimentary nitrogen uptake and assimilation in the temperate zooxanthellate sea anemone Anthopleura aureoradiata

The sea anemone Anthopleura aureoradiata (Carlgren), which harbours symbiotic dinoflagellates (zooxanthellae), is abundant on mudflats and rocky shores around New Zealand. We measured the potential for particulate nitrogen uptake from sediment by A. aureoradiata and the subsequent consequences of this uptake on the nitrogen status of its zooxanthellae. Sediment was rinsed, labelled with (¹⁵NH₄)₂SO₄, and provided to anemones at low (0.23 g ml^− 1) and high (1.33 g ml^− 1) sediment loads for 6 h. Both anemone tissues and zooxanthellae became enriched with ¹⁵N. Enrichment of anemone tissues was similar at both high and low sediment loads, but the zooxanthellae became more enriched at the lower load. This was presumably because the uptake of ammonium, arising from host catabolism, by zooxanthellae is light driven and because the anemones at the lower load were able to extend their tentacles into the light while those at the higher load were not. The influence of sediment uptake on the nitrogen status of the zooxanthellae was determined by measuring the extent to which 20 μM NH₄⁺ enhanced the rate of zooxanthellar dark carbon fixation above that seen in filtered seawater (FSW) alone; the ammonium enhancement ratio (AER) was expressed as [dark NH₄⁺ rate/dark FSW rate], where ‘rate’ refers to C fixation and a ratio of 1.0 or less indicates nitrogen sufficiency. When anemones were starved with and without rinsed sediment in nitrogen-free artificial seawater for 8 weeks, zooxanthellar nitrogen deficiency became apparent at 2-4 weeks and reached similar levels in both treatments (AER = ~ 2). In contrast, anemones fed 5 times per week for 8 weeks with Artemia nauplii were nitrogen sufficient (AER = 1.03). In the field, zooxanthellae from mudflat anemones were largely nitrogen sufficient (AER = 1.26), while nitrogen deficient zooxanthellae were present in anemones from a rocky intertidal site (AER = 2.93). These results suggest that, while there was evidence for particulate nitrogen uptake, dissolved inorganic nitrogen (especially ammonium) in interstitial pore water may be a more important source of nitrogen for the zooxanthellae in mudflat anemones, and may explain the marked difference in nitrogen status between the mudflat and rocky shore populations.     

The Uptake of Growth Substances: IX. FURTHER STUDIES OF THE MECHANISM OF UPTAKE OF 2,3,6-TRICHLOROBENZOIC ACID BY AVENA SEGMENTS

In a previous paper it was established that during the courseof uptake of radioactive 2,3,6-trichlorobenzoic acid (2,3,6-TCBA)by mesocotyl segments of Avena, the rate, initially positive,became negative within six hours. This phase of net loss isprevented by streptomycin and by synthalin, while an enhancementof accumulation is brought about by cetyl trimethylammoniumbromide (CTAB). It was postulated that the initial accumulationis governed by an unstable accumulatory process (Type 1) whichinvolves adsorption by some cell membrane system through aninteraction between the carboxyl anion of the growth-regulatormolecule and the quaternary ammonium group of the choline moietyof -lecithin. Hydrolysis of lecithin by phospholipase-D destroysthis Type 1 binding, while cationic nitrogen compounds maintainpositive uptake by competing with the choline quaternary ammoniumgroup of -lecithin for the anionic site of phospholipase-D. The effects of pretreatment at a low temperature on the subsequentuptake of 2,3,6-TCBA and the influence of pH on the course ofuptake, as well as studies of the egress of choline, providesome support for the role of phospholipase-D in determiningthe instability of the accumulatory system. Synthalin and CTAB inhibit the activity of phospholipase-D invitro. However, other investigations with this enzyme alsoemphasize that such inhibition can only partially account forthe great enhancement of the uptake of TCBA produced by CTAB.Related experiments on the uptake of alkyl pyridinium compoundsby Avena segments and on their adsorption to lecithin in vitrofavour a suggestion that quaternary ammonium compounds, suchas CTAB, act largely by providing aftificial Type 1 sites. The mechanism and significance of Type 1 accumulation are discussedand compared with similar postulates for the binding of auxinsand salts.     

The Assimilation of Nitrogen from Ammonium Salts and Nitrate by Fungi

1. The assimilation of inorganic nitrogen by Scopulariopsis brevicaulisand some physiologically similar species has been studied. Theirfailure to assimilate completely from ammonium sulphate hasbeen shown to be due to the fall in pH of the medium inducedby the initial uptake of ammonia.
2. Complete assimilation ofammonia takes place in the presenceof the neutral salts ofeach of thirteen organic acids investigated.The organic acidsact primarily through their buffering effectwhich preventsor slows down the fall in pH. They are not specificallyrequiredfor ammonia assimilation by these fungi and can beeffectivelyreplaced by certain inorganic buffers.
3. The influence of severalexternal factors on the rate of assimilationof ammonia, nitrate,and nitrite has been studied in S. brevicaulis.In correspondingconditions the mycelium assimilates ammoniamore rapidly thannitrate over a wide range of conditions.
4. Ammonia, even invery low concentration, completely suppressesnitrate assimilationwhen both sources of nitrogen are presenttogether. Nitrite,however, is assimilated simultaneously withammonia. It is thereforeconcluded that ammonia blocks the reductionof nitrate to nitriteby the fungus.
5. The suppression of nitrate assimilation inthe presence of ammoniais common to many mould fungi besidesS. brevicaulis, and isbelieved to have adaptive significancein natural habitats.
6. The nitrate-reducing and assimilatingsystem is formed, evenwhen S. brevicaulis is grown in completeabsence of nitrate(ammonia medium with organic acid). It comesinto action rapidlywhen the inhibiting effect of ammonia isremoved. Similarly,nitrate-grown mycelium is capable of assimilatingammonia atmaximal rate without any adaptive lag.

     

Mechanism and regulation of folate uptake by human pancreatic epithelial MIA PaCa-2 cells

After the liver, the pancreas contains the second highest level of folate among human tissues, and folate deficiency adversely affects its physiological function. Despite that, nothing is currently known about the cellular mechanisms involved in folate uptake by cells of this important exocrine organ or about folate uptake regulation. We have begun to address these issues, and in this report we present the results of our findings on the mechanism of folate uptake by the human-derived pancreatic MIA PaCa-2 cells. Our results show folic acid uptake to be 1) temperature and energy dependent; 2) pH dependent, with a markedly higher uptake at acidic pH compared with neutral or alkaline pH; 3) Na⁺ independent; 4) saturable as a function of substrate concentration (apparent K_m = 0.762 ± 0.10 µM); 5) inhibited (with similar affinity) by reduced, substituted, and oxidized folate derivatives; and 6) sensitive to the inhibitory effect of anion transport inhibitors. RT-PCR and Western blot analysis showed expression of the human reduced folate carrier (hRFC) at the RNA and protein levels, respectively. The functional contribution of hRFC in carrier-mediated folate uptake was confirmed by gene silencing using gene-specific small interfering RNA. Evidence also was found suggesting that the folate uptake process by MIA PaCa-2 cells is regulated by cAMP- and protein tyrosine kinase (PTK)-mediated pathways. These studies demonstrate for the first time the involvement of a specialized, acidic pH-dependent, carrier-mediated mechanism for folate uptake by human pancreatic MIA PaCa-2 cells. The results also show the involvement of hRFC in the uptake process and suggest the possible involvement of intracellular cAMP- and PTK-mediated pathways in the regulation of folate uptake. human reduced folate carrier; small interfering RNA; transport regulation