Modelling of the flows and partitioning of carbon and nitrogen in the holoparasite Cuscuta reflexa Roxb. and its host Lupinus albus L.: II. Flows between host and parasite and within the parasitized host

A recently developed empirically based modelling technique wasused to quantify uptake, flow and utilization of C and N inLupinus albus L., uninfected and parasitized by Cuscuta reflexaRoxb. plants over a 12 d period during flowering and early fruitsetting of the host. The modelling combined data on molar C:Nratios in host phloem and pressure-induced xylem sap, net incrementsof C and N in host and parasite plant parts and respiratorylosses of C. The modelling of the solute transfer between hostand Cuscuta was achieved by assuming non-specific intake fromthe xylem. The models predicted that Cuscuta derived 99.5% ofits carbon and 93.6% of its nitrogen demand from the host phloem.The overriding sink strength of the parasite diverted most ofthe basipetally translocated host assimilates and massivelycompeted with the host root and inhibited fruit setting. Carbonincorporation in Cuscuta consumed 56%, respiration 24% and secretionby extrafloral nectaries 1.8% of the current host photosynthate.Root respiration was inhibited by 59% and carbon was mobilizedfrom host root and leaves. Competition by the parasite for Nwas even more severe and Cuscuta incorporated nitrogen equalling223% of current fixation, but N₂ fixation of the host was severelyrestricted to 37%. Withdrawal of N from host phloem led to severelosses of N from leaves and the root and marked decreases inN concentration. It required massive xylem-to-phloem transferof N, because the xylem as the major supply route for N wasnot exploited substantially by Cuscuta. The results are discussedin relation to likely causes for parasite-induced pathogeniceffects, suggesting that Cuscuta affected the host adverselyby depriving it mainly of its nitrogen, but that causal to incipientnitrogen deficiency and restricted N2 fixation was the superiorsink potential of Cuscuta, which prevented adequate supply ofassimilates to the nodulated root. The dominating sink potentialof Cuscuta is compared with the similarly strong sink competitionexerted by fruits at the stage of seed filling in annual plants. Key words: Cuscuta reflexa, Lupinus albus, parasitism, carbon, nitrogen, phloem, xylem, transport     

Sink-stimulated photosynthesis, increased transpiration and increased demand-dependent stimulation of nitrate uptake: nitrogen and carbon relations in the parasitic association Cuscuta reflexa-Coleus blumei

When parasitizing Coleus blumei Benth., grown in quartz sandculture and fed with 0.2, 1 or 5 mM nitrate, the biomass productionof Cuscuta reflexa Roxb. was inhibited to a similar extent asthat of the host supplied limiting concentrations of nitrate.In the presence of Cuscuta the growth and dry matter increaseof the host plant was severely inhibited. However, dry matterproduction of host plus parasite was only slightly less thanor at 0.2 mM nitrate almost the same as that of uninfected Coleusplants. Under all conditions of nitrate nutrition, parasitismby Cuscuta led to a substantial increase in photosynthesis inhost leaves under light-saturating conditions and in transpiration.Particularly with 0.2 mM and mM     

Cuscuta reflexa invasion induces Ca2+ release in its host

Cuscuta reflexa induces a variety of reaction in its hosts. Some of these are visual reactions, and it is clear that these morphological changes are preceded by events at the molecular level, where signal transduction is one of the early processes. Calcium (Ca²⁺) release is the major second messenger during signal transduction, and we therefore studied Ca²⁺ spiking in tomato during infection with C. reflexa. Bioluminescence in aequorin‐expressing tomato was monitored for 48 h after the onset of Cuscuta infestation. Signals at the attachment sites were observed from 30 to 48 h. Treatment of aequorin‐expressing tomato leaf disks with Cuscuta plant extracts suggested that the substance that induced Ca²⁺ release from the host was closely linked to parasite haustoria.     

Modelling the flow and partitioning of carbon and nitrogen in the holoparasite Cuscuta reflexa Roxb. and its host Lupinus albus L.: I. Methods for estimating net flows

Nodulated Lupinus albus L. was grown on quartz sand in the greenhouseand supplied with a N-free culture solution. Half the plantswere infected with Cuscuta reflexa Roxb. at 33 DAS. An empiricallybased modelling technique was developed to quantitatively depictuptake, flow and utilization of C and N in the host plant andbetween host and parasite over a 12 d period. The modellingincorporated C: N ratios of solutes in phloem and pressure-inducedxylem sap, net increments of C and N and respiratory lossesof C. For assessing the transfer of solutes from host phloemto Cuscuta it was not possible to use the C: N ratio of phloemsap close to the site of parasite attachment, a procedure whichwould have assumed non-specific withdrawal of phloem-borne solutes,since this would have implied unimpeded mass flow from hostto parasite. The relative intake of C and N by the parasiteby specific withdrawal of nitrogenous and carbonaceous solutesfrom the phloem was obtained independently by assuming thatxylem intake occurred non-specifically. Xylem import was thusobtained (a) from transpiration and tissue water increment ofCuscuta and the concentrations of N and C in xylem sap and (b)from the Ca²⁺ increment of Cuscuta and the ratios Ca: N andCa: C in lupin xylem sap, assuming that Ca²⁺ intake occurredsolely via xylem. By subtracting net xylem import from totaluptake of C and N by Cuscuta the methods resulted in comparableratios of C: N intake from the phloem. The average ratio (53.4)was smaller than the C:N ratio in host phloem (85.6) indicatingspecific withdrawal of solutes with a distinct preference forN. Using this ratio, modelling of flows of C and N was possibleand showed that Cuscuta abstracted C and N mainly from the hostphloem, but xylem supply was nutrient-dependent and amountedto 6.4% of the N but only 0.5% of the C demand. The resultsindicated that Cuscuta exerted a very strong sink and competedefficiently with the root, the major sink of L. albus, by attracting81% of the current photosynthate and more N (223%) than wascurrently fixed. The massive demand of the parasite led to lossesparticularly of N from leaves and the root and apart from causingcarbon losses it appeared to induce a sink-dependent stimulationof photosynthesis. In contrast, nitrogen fixation in the Cuscuta-infectedlupin was inhibited to 37% of the control. Key words: Cuscuta reflexa, Lupinus albus, carbon, nitrogen, phloem, xylem, transport, parasites, modelling     

Über das Vorkommen eines cytokininartigen Faktors inCuscuta reflexa

Zusammenfassung InCuscuta reflexa-Extrakten konnte mit Hilfe verschiedener biologischer Teste ein cytokininartiger Faktor nachgewiesen werden. Die Bedeutung dieses Faktors für das Verhältnis zwischen derCuscuta und ihren Wirtspflanzen wird diskutiert.

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On the existence of a cytokinin-like factor in cuscuta reflexa

Summary In extracts ofCuscuta reflexa Roxb. a cytokinin like factor (CAF = Cuscuta active factor) was found. It was shown that activity of this factor is similar to that of kinetin in all essential points. In tobacco-stem-tissue tests a promotion of growth by CAF was observed. In chlorophyll-preservation tests CAF produced a strong inhibition of chlorophyll dissimilation. Moreover in tests with¹⁴C-labelled glycine a migration of the glycine and other amino acids due to CAF was found.The occurrence of the observed cytokinin-like factor inCuscuta reflexa is discussed with respect to the parasite-host relations ofCuscuta.

     

Modelling of quinolizidine alkaloid net flows in Lupinus albus and between L. albus and the parasite Cuscuta reflexa: new insights into the site of quinolizidine alkaloid synthesis

The present work reveals new and completely different conclusionsabout the alkaloid economy of symbiotically fed Lupinus albusand L. albus parasitized by Cuscuta reflexa in the study periodof 43–55 d after sowing of lupin. Net flows of alkaloidswithin lupin and between host and parasite were calculated usingthe molar ratio of alkaloid nitrogen: total nitrogen combinedwith known net flows of nitrogen in the transport fluids andanalysing alkaloid accumulation in plant organs by HRGC. Incontrast to previous studies, quinolizidine alkaloids were predictedto be synthesized mainly in the root of L. albus and to be predominantlytransported via xylem to the apical plant shoot organs. Parasitismby C. reflexa for 12 d induced a decline of alkaloid contentin the host L. albus up to 53% compared to control plants andalkaloid synthesis was halved—apparently due to a shortageof the precursor lysine. In spite of an additional decreasein nitrogen levels at the second harvest, the host-parasitesystem showed a1.3-fold higher alkaloid content than the controlplants, 63% of the total alkaloids being attracted by Cuscuta.This indicates (a) restriction of catabolic processes withininfected lupins, (b) a massive shift of nitrogen metabolismin the direction of alkaloids and (c) an enormous sink potentialof Cuscuta for nitrogenous compounds. Although xylem was foundto be the main translocation system for alkaloids, the modellingof alkaloid flows predicts Cuscuta to derive only 4.5% of itstotal alkaloid supply from the xylem and 95.5% from the phloem.By analogy with nitrogen flows, this finding requires xylemphloemtransfers which were assumed to occur within the stem axis oflupin. A similar proportion regarding the contribution of xylemand phloem to the supply of Cuscuta was obtained for the netflows of two selected alkaloids, lupanine and 13     

Complete DNA sequences of the plastid genomes of two parasitic flowering plant species, <Emphasis Type="Italic">Cuscuta reflexa</Emphasis> and <Emphasis Type="Italic">Cuscuta gronovii</Emphasis>

Background  

The holoparasitic plant genus Cuscuta comprises species with photosynthetic capacity and functional chloroplasts as well as achlorophyllous and intermediate forms with restricted photosynthetic activity and degenerated chloroplasts. Previous data indicated significant differences with respect to the plastid genome coding capacity in different Cuscuta species that could correlate with their photosynthetic activity. In order to shed light on the molecular changes accompanying the parasitic lifestyle, we sequenced the plastid chromosomes of the two species Cuscuta reflexa and Cuscuta gronovii. Both species are capable of performing photosynthesis, albeit with varying efficiencies. Together with the plastid genome of Epifagus virginiana, an achlorophyllous parasitic plant whose plastid genome has been sequenced, these species represent a series of progression towards total dependency on the host plant, ranging from reduced levels of photosynthesis in C. reflexa to a restricted photosynthetic activity and degenerated chloroplasts in C. gronovii to an achlorophyllous state in E. virginiana.     

Significance of Cuscutain,a cysteine protease from <Emphasis Type="Italic">Cuscuta reflexa</Emphasis>, in host-parasite interactions

Background  

Plant infestation with parasitic weeds like Cuscuta reflexa induces morphological as well as biochemical changes in the host and the parasite. These modifications could be caused by a change in protein or gene activity. Using a comparative macroarray approach Cuscuta genes specifically upregulated at the host attachment site were identified.     

Morphological and plant hormonal changes during parasitization by Cuscuta japonica on Momordica charantia

The holostemparasitic plant Cuscuta parasitizes various plants and sucks nutrients from the host stem. We used Cuscuta japonica as the parasite and Momordica charantia as the host plant, and described their interaction. The parasitized Momordica stems started swelling as a hypertrophic response within 3 days after parasitization. Concurrently, the Cuscuta stem grew rapidly and developed bigger scale leaves than usual. Parasitized Momordica stems reduced photosynthetic activity. Histological observation revealed no programmed cell death but an increased number of vascular bundles in the Momordica stem, especially near the Cuscuta hyphae. The defensive response of Momordica mainly involved the SA pathway. Drastic increase of tZ- and DZ-type cytokinins in Momordica stems would play an important role for hypertrophy. Cuscuta had higher cZ endogenously and our results imply that each subtype of CK might play different roles during parasitization process. Comprehensive plant hormone analysis provides new insights into plant interaction studies.     

Selective mineral transport barriers at Cuscuta-host infection sites

The uptake of inorganic nutrients by rootless parasitic plants, which depend on host connections for all nutrient supplies, is largely uncharted. Using X-ray fluorescence spectroscopy (XRF), we analyzed the element composition of macro- and micronutrients at infection sites of the parasitic angiosperm Cuscuta reflexa growing on hosts of the genus Pelargonium. Imaging methods combining XRF with 2-D or 3-D (confocal) microscopy show that most of the measured elements are present at similar concentrations in the parasite compared to the host. However, calcium and strontium levels drop pronouncedly at the host/parasite interface, and manganese appears to accumulate in the host tissue surrounding the interface. Chlorine is present in the haustorium at similar levels as in the host tissue but is decreased in the stem of the parasite. Thus, our observations indicate a restricted uptake of calcium, strontium, manganese and chlorine by the parasite. Xylem-mobile dyes, which can probe for xylem connectivity between host and parasite, provided evidence for an interspecies xylem flow, which in theory would be expected to carry all of the elements indiscriminately. We thus conclude that inorganic nutrient uptake by the parasite Cuscuta is regulated by specific selective barriers whose existence has evaded detection until now.     

Physiological and ecological warnings that dodders pose an exigent threat to farmlands in Eastern Africa

Invasive holoparasitic plants of the genus Cuscuta (dodder) threaten African ecosystems due to their rapid spread and attack on various host plant species. Most Cuscuta species cannot photosynthesize and hence rely on host plants for nourishment. After attachment through a peg-like organ called a haustorium, the parasites deprive hosts of water and nutrients, which negatively affects host growth and development. Despite their rapid spread in Africa, dodders have attracted limited research attention, although data on their taxonomy, host range, and epidemiology are critical for their management. Here, we combine taxonomy and phylogenetics to reveal the presence of field dodder (Cuscuta campestris) and C. kilimanjari (both either naturalized or endemic to East Africa), in addition to the introduction of the giant dodder (C. reflexa), a south Asian species, in continental Africa. These parasites have a wide host range, parasitizing species across 13 angiosperm orders. We evaluated the possibility of C. reflexa to expand this host range to tea (Camelia sinensis), coffee (Coffea arabica), and mango (Mangifera indica), crops of economic importance to Africa, for which haustorial formation and vascular-bundle connections in all three crops revealed successful parasitism. However, only mango mounted a successful postattachment resistance response. Furthermore, species distribution models predicted high habitat suitability for Cuscuta spp. across major tea- and coffee-growing regions of Eastern Africa, suggesting an imminent risk to these crops. Our findings provide relevant insights into a poorly understood threat to biodiversity and economic wellbeing in Eastern Africa, and provide critical information to guide development of management strategies to avert Cuscuta spp. spread.

Microscopy and habitat suitability modeling provide an early warning that dodder’s invasion in Eastern Africa poses a threat to important cash crops.     

Metabolite changes with induction of Cuscuta haustorium and translocation from host plants

Cuscuta is a stem holoparasitic plant without leaves or roots, parasitizing various types of host plants and causing major problems for certain crops. Cuscuta is known as a generalist and, thus, must have unique parasite strategies to cope with different host plants. For elucidating metabolic responses and mechanisms of parasitization, metabolomic approaches using GC/MS were applied. We compared five stages of Cuscuta japonica: early stage seedlings, with far red light (FR) cue, with contact signal, haustorium induced seedlings by both signals and adult plant parasites on host plants. Sugars, amino acids, organic acids, nucleic acids, and polyols were identified from the polar phase fraction. The apical part contained metabolite profiles different from the haustorium induced part or the basal part. Amino acid and some organic acids were up-regulated for haustorium induction but decreased after parasitization. After attachment to different host plants, metabolite profiles of Cuscuta japonica changed dramatically due to the absorption of specific host plant metabolites such as pinitol. Cuscuta seedlings attached to pinitol rich host plants contained more pinitol and showed different profiles from those attached to plants having less or lacking pinitol.     

Diversity,evolution, and function of stomata bearing structures in Cuscuta (dodders,Convolvulaceae): From extrafloral nectar secretion to transpiration in arid conditions

Cuscuta includes ca. 200 species of functionally holoparasitic plants grouped in four subgenera: Monogynella, Cuscuta, Pachystigma, and Grammica. Multicellular structures with stomata in Cuscuta are represented by extrafloral nectaries (ENs), reported from the stems of one Monogynella species, and stomatiferous protuberances (SPs), which are non-secretory. These latter structures had been noted on the stems of three Grammica species more than a century ago but entirely forgotten until recently when similar, non-secretory SPs were reported on the flowers of several new Grammica species. Here we study for the first time: (1) the extent of occurrence, diversity and evolution of secretory (ENs) and non-secretory (SPs) multicellular structures in Cuscuta, and (2) the function of SPs. We undertook a character evolution study of ENs and SPs on the stems and flowers of 136 Cuscuta taxa, and examined the structure/ultrastructure of SPs. ENs are inferred as primitive and characterize subg. Monogynella. SPs are derived in the remaining subgenera; they are ubiquitous on the flowers of Cuscuta and Pachystigma, but absent on their stems. Subgenus Grammica species develop two functional types of stems during their life cycle: vegetative, exploratory stems with very low stomatal densities (and no SPs), and reproductive, haustorial stems with numerous SPs. Moreover, 24 species from nine clades of subg. Grammica have evolved morphologically diverse floral SPs with systematic significance. To preliminarily ascertain SP function, we determined in the field the water uptake of Tithonia tubiformis plants parasitized or not by Cuscuta costaricensis, a species with both stem and floral SPs, and the stomatal conductance of dodder stems and flowers, as well as host leaves. Water uptake of parasitized hosts was significantly higher compared to non-parasitized plants, even after host leaves were removed, both during the day and night. The increased water uptake of parasitized hosts and stomatal conductance values suggest a transpiration role for the SPs, which is also confirmed by their lacunar structure. Grammica species with floral SPs grow in arid areas or characterized by a pronounced dry season during flowering/fruiting, which suggests that SPs may have evolved to stimulate the host water uptake during these phenophases.     

Functional loss of all ndh genes in an otherwise relatively unaltered plastid genome of the holoparasitic flowering plant Cuscuta reflexa

We have cloned and sequenced an area of about 9.0 kb of the plastid DNA (ptDNA) from the holoparasitic flowering plant Cuscuta reflexa to investigate the evolutionary response of plastid genes to a reduced selective pressure. The region contains genes for the 16S rRNA, a subunit of a plastid NAD(P)H dehydrogenase (ndhB), three transfer RNAs (trnA, trnI, trnV) as well as the gene coding for the ribosomal protein S7 (rps7). While the other genes are strongly conserved in C. reflexa, the ndhB gene is a pseudogene due to many frameshift mutations. In addition we used heterologous gene probes to identify the other ndh genes encoded by the plastid genome in higher plants. No hybridization signals could be obtained, suggesting that these genes are either lost or strongly altered in the ptDNA of C. reflexa. Together with evidence of deleted genes in the ptDNA of C. reflexa, the plastid genome can be grouped into four classes reflecting a different evolutionary rate in each case. The phylogenetic position of Cuscuta and the significance of ndh genes in the plastid genome of higher plants are discussed.     

Marked effect of Cuscuta on puerarin accumulation in cell cultures of Pueraria tuberosa grown in shake flasks and a bioreactor

Isoflavonoid production in cell cultures of Pueraria tuberosa as influenced by an angiospermic parasite, Cuscuta reflexa, was studied. During the time course, maximum isoflavonoid content was recorded when Cuscuta elicitor was added on day 15 of culture. Among various concentrations of elicitor tried, 1 g l⁻¹ of Cuscuta elicitor was found to be the most effective. The optimized elicitation conditions were used in vessels of varying capacity where maximum yield of ~91 mg l⁻¹ of isoflavonoid was recorded in a 2-l bioreactor which was about 19% higher than the control cultures. In this case, puerarin content increased up to 11 mg l⁻¹ which was 580% higher that the value recorded in the control cultures. In the bioreactor, 8 days of elicitation was optimal for the high accumulation of isoflavonoid, giving productivity of ~4 mg l⁻¹ day⁻¹. The study showed persistent high isoflavonoid yield even during scale-up. Use of a preparation of Cuscuta reflexa as an elicitor is reported for the first time. The increase in isoflavonoid content was elicitor dose-dependent and can be explored to trigger high yields of isoflavonoid/secondary metabolites in production.     

Macromolecular trafficking between Nicotiana tabacum and the holoparasite Cuscuta reflexa

Transgenic tobacco plants expressing green fluorescent protein (GFP) under the control of the companion cell-specific promoter, AtSUC2, were parasitized by the holoparasite Cuscuta reflexa (dodder). GFP, moving in the translocation stream of the host, was transferred to the Cuscuta phloem via the absorbing hyphae of the parasite. An identical pattern of transfer was observed for the phloem-mobile probe, carboxyfluorescein. Following uptake by the parasite, GFP was translocated and unloaded from the Cuscuta phloem in meristematic sink tissues. Contrary to published data, these observations suggest the presence of a functional symplastic pathway between Cuscuta and its hosts, and demonstrate a considerable capacity for macromolecular exchange between plant species.     

Ca uptake and plasma membrane depolarization associated with blue light-sensitive exogenous NADH oxidation by Cuscuta protoplasts

Protoplasts isolated from the apical segments of Cuscuta reflexa exhibited blue light-sensitive PM-linked NADH oxidase activity and increased rate of Ca²⁺-uptake in presence of NADH in dark, which was also stimulated by blue light. Contrary to marginal inhibition by Con A treatment, the ATPase inhibitors significantly inhibited the Ca²⁺ uptake by the protoplasts both in dark and under blue light. The Ca²⁺-calmodulin antagonists, W-7 and calmidazolium, also inhibited Ca²⁺-uptake by protoplasts under similar conditions. The state of PM polarization was monitored by the fluorescent dye 9-amino acridine. It was observed that PM-linked NADH oxidation caused hyperpolarization of the membrane, the exposure of which to blue light resulted in membrane depolarization. The presence of Ca²⁺-calmodulin antagonists or Con A treatment completely abolished the blue light-induced membrane depolarization. It is argued that these actities at the PM, having some glycoproteic components, are functionally closely involved in blue light-induced signal transduction in Cuscuta     

Cell Wall Degrading Enzymes in Cuscuta reflexa and Its Hosts

Pectin degrading enzymes, hemicellulose degrading enzyme andcellulose degrading enzymes were studied in Cuscuta reflexaRoxb., its susceptible hosts, Brassica campestris L., Cocciniaindica W. & A. Datura innoxia Mill, Helianthus annuus L.,Holoptelea indica Planch, Lantana camara L., Medicago sativaL., Manihot utilissima Pohl, Petunia hybrida X Hort exvilm,Pisum sativum L., Phaseolus vulgaris L. and Solanum nigrum L.and non-susceptible plants Ipomoea batata Lam. and Solanum tuberosumL. Pectin esterase and polygalacturonase were present in higheramounts in Cuscuta parasitic on P. vulgaris and S. nigrum, whichneeded more time for haustorial establishment. Exo-l, 4-ß-D-glucosidaseactivity was found in Cuscuta but could not be detected in itshosts. Xylanase and cellulase activity of host plants increasedwhile cellobiase activity decreased as a result of infectionby the parasite. Higher pectin esterase, polygalacturonase,xylanase and exo-l, 4-ß-D-glucosidase activities inthe haustorial region of the parasite is likely to bring aboutthe lysis of the cell wall of the host plant and thus facilitatethe penetration of the parasite haustoria into the host sieveelement, which is necessary for the transport of nutrients betweenthe host and the parasite. Key words: Cell wall degrading enzymes, Cuscuta reflexa     

Diet mixing in a parasitic plant: adaptation or constraint?

Some herbivores deliberately consume a mixed diet, either to obtain a superior mix of nutrients or to avoid consuming too much of any one toxin. Few studies have examined diet mixing in parasitic plants, which typically have very broad host ranges. We offered the parasitic plant Cuscuta indecora (dodder), a range of mixtures of two hosts (Iva frutescens and Borrichia frutescens) in the greenhouse, and observed correlations between the host community and Cuscuta infection in the field. In the greenhouse, Cuscuta performed better on mixtures with a higher relative abundance of Iva. Cuscuta selectively foraged on whichever host was more abundant (diet switching), the exact opposite of the behavior that would be expected if diet mixing was advantageous. In the field, the intensity of Cuscuta infections was decreased by the presence of non-hosts (grasses), not strongly affected by the presence of intermediate hosts, and increased by the presence of Borrichia. We conclude that Cuscuta does not obtain nutritional benefits from a broad diet, but instead is constrained by its relative lack of mobility to attack hosts of intermediate value. In general, the lack of mobility of parasitic plants compared to herbivores probably selects for broad host ranges in parasitic plants.     

Transfer of amino acids and nitrate from the roots into the xylem of Ricinus communis seedlings

The loading of amino acids and nitrate into the xylem was investigated by collection and analysis of root-pressure exudate from the cut hypocotyl stumps of seedlings of Ricinus communis L. Glutamine was found to be the dominant amino acid in the exudate and also to be the amino acid which is transferred to the xylem most rapidly and accumulated to the greatest extent. The comparison between uptake and xylem loading showed significant differences in specificity between these two transport reactions, indicating a different set of transport systems. Nitrate is transferred to the xylem at a higher relative rate than any amino acid despite the great nitrate-storage capacity of the root system. Thus the supply of nitrate to Ricinus plants leads to enhanced nitrogen allocation to the shoots.