Glucose Induced H+ Influx and Transient Currents in Excised Roots: particularly those of Zea mays

The application of D-glucose to solutions bathing excised maize,wheat, pea and bean roots causes a rapid depolarization of theelectrical potentials between the cut tops of the roots andthe bathing solutions. Similar effects are observed for theplasma membrane potentials of maize lateral roots. A flow cell apparatus was used to demonstrate qualitative andquantitative relations between glucose induced H⁺ influx andthe transient decrease in current through the root. The currentchanges appear to be due entirely to H⁺ fluxes. Current andH⁺ fluxes are strongly influenced by external pH, the optimumpH for glucose induced current change being about 4.0. A similarpH optimum was found for 3-O-methyl-D-glucopyranoside but 1-O-methyl--D-glucopyranosidedid not significantly affect the trans-root potential at anypH, suggesting a significant role for the anomeric hydroxylgroup of glucose. Compounds which depolarize the trans-root potential also inhibitthe glucose induced depolarization. Surface -SH groups are probablynot involved in the glucose/H⁺ cotransport. Eadie-Hofstee plots relating the depolarization of trans-rootpotential to the concentrations of D-glucose or 3-O-methyl-D-glucopyranosidehave shown that K_m values increase with increasing monosaccharideconcentration and are very similar to reported values of 3-O-methyl-D-glucopyranosideuptake in maize root segments. K_m values for a similar rangeof D-glucose concentrations do not vary significantly with pHor with membrane depolarization due to a 10-fold increase ofKCl concentration. However, V_max is lowered by an increase inexternal pH or a decrease in trans-root potential. It appearsthat both proton and electrical gradients can affect glucoseinduced H⁺ influx. The auxin herbicide, 2, 4-dichlorophenoxyethanoic acid (0.01mM) stimulates the glucose induced depolarizations in a mannerconsistent with an increase in cytoplasmic pH. This is discussedin relation to the reported action of indole-3-acetic acid andfusicoccin on maize root tissue.     

Isolation of 1-O-trans-p-Coumaroyl-r{beta}-D-glucopyranose from Sweet Potato Roots and Examination of Its Role in Chlorogenic Acid Biosynthesis

1-O-trans-p-Coumaroyl-rß-D-glucopyranose (p-coumaroyl-D-glucose)was isolated from slices of sweet potato root which had beenincubated with trans-cinnamic acid. Pre-loaded trans-cinnamicacid efficiently trapped the radioactivity from L-[U-¹⁴C]-phenylalanineand reduced its incorporation into chlorogenic acid by 75% ofcontrol values in disks of sweet potato root. In the root diskssupplied with trans-[3-¹⁴C]-cinnamic acid, the radioactivitywas transferred first to trans-cinnamoyl- D-glucose, then top-coumaroyl-D-glucose, and subsequently to chlorogenic acidand isochlorogenic acid. These results support our earlier propositionthat p-coumaroyl-D-glucose is involved in the biosynthesis ofchlorogenic acid as an intermediate adjacent in the pathwayto trans-cinnamoyl-D-glucose in sweet potato roots. (Received April 11, 1988; Accepted August 9, 1988)     

A Lectin from Leaves of Neoregelia flandria Recognizes D-Glucose, D-Mannose and N-Acetyl D-glucosamine, Differing from the Mannose-Specific Lectins of Other Monocotyledonous Plants

A mannose-specific lectin was isolated from leaves of Neoregeliaflandria, an ornamental plant that belongs to Bromeliaceae,a family of monocotyledons. The amino acid composition and molecularmass of the lectin were similar to those of mannose-specificlectins from other monocotyledons. However, in a test to examinethe inhibition of hemagglutination, it became apparent thatthe isolated lectin recognized D-glucose and N-acetyl D-glucosaminein addition to D-mannose, unlike mannose-specific lectins fromthe monocotyledons that have been reported to date. (Received May 17, 1996; Accepted August 19, 1996)     

Analysis of In Vivo Protein Synthesis and Histological Studies of Haustorial Formation in Root Cultures of Witch weed (Striga asiatica L Kuntze)

We recently described an in vitro approach that uses root culturesto study haustorial formation in Striga asiatica. Previous studieshave used haustoria formed on intact radicles of Striga seedlings.In vitro cultured roots formed haustoria that appeared morphologicallysimilar to those formed by Striga radicles, but were 5–10-foldlarger. In this study, we provide biochemical and histologicalevidence to support further the similarity of root culture haustoriato haustoria formed on radicles of seedlings. We examined invivo protein synthesis during haustorial development on rootcultures and radicles by 2-D PAGE. Four proteins increased inabundance in both root cultures and radicles after 6 h of haustorialinduction. All four proteins appeared transiently in root culturesand radicles, being more abundant at 6 h, and less abundantafter 24 h of haustorial induction. Only three of the four haustorial-specificproteins were more abundant in root cultures after 2 h of haustorialinduction; all four had decreased in abundance after 12 h ofhaustorial induction. Using light microscopic analysis we comparedthe ontogeny of root culture haustoria to that of haustoriaon radicles. These studies revealed that root culture haustoriaundergo developmental changes similar to those reported forradicle haustoria such as early expansion of cortical cells,the emergence of haustorial hairs from epidermal cells, andthe development of densely staining cells at the haustorialapex. In addition, these changes occurred within a similar time-frameand sequence in root culture and radicle haustoria. Finally,root culture haustoria were found to be capable of attachingto sorghum host roots. Key words: Striga asiatica L., Kuntze, haustoria, root cultures, proteins, histology, 2D-PAGE     

Transport pathways in canine lingual epithelium involved in sweet taste

The responses of canine lingual epithelium to D-glucose weremeasured in an Ussing chamber to determine the possible contributionof the osmotic changes of taste cells to the response of saccharides.With the mucosal solution containing 50 mM NaCl, 2 mM HEPES,pH 7.4 (solution A) and the serosal solution containing Krebs—Henseleit(KH) buffer the addition of up to 0.5 M D-glucose in the mucosalsolution increased the short circuit current (I_sc) in a sigmoidalmanner. The D-glucose-stimulated I_sc was inhibited by 0.1 mMamiloride or 1 mM ouabain added to either the mucosal or theserosal solution, and partially inhibited by 5 mM BaCl₂ addedto the serosal solution. The inhibition by these three compoundswas also observed in the presence of 0.5 M NaCl. Ouabain alsoinhibited transport when added to solution A. These experimentssuggest that in canine lingual epithelium the paracellular pathwaypermits molecules as large as ouabain (mol. wt 586) to diffusefrom the mucosal to the serosal solution and vice versa underall osmotic conditions. These results may explain the phenomenonof intravascular taste. Such is not the case in rat tongue whereouabain only inhibited transport when added to the serosal solution.Increasing the osmolality of the serosal KH buffer by additionof relatively membrane-impermeable saccharides such as sucroseor L-glucose did not significantly alter the I_sc, whereas makingthe serosal KH solution hypo-osmotic resulted in a transientdecrease in I_sc. These data suggest that the increase in I_scinduced by saccharides, such as D-glucose, is not simply anosmotic response of the epithelium but more likely the consequenceof saccharides binding weakly to receptors. That the responseto both salts by themselves and in the presence of saccharidesexhibits the same cation selectivity, and that both are inhibitedby amiloride, ouabain, BaCl₂ and LaCl₃ suggest that in caninelingual epithelia, in contrast to rat epithelium, the responsesto hyperosmotic concentrations of salts and saccharides mightoccur via the same transcellular pathways.     

Heterogeneity in spatial P-distribution and foraging capability by Zea mays: effects of patch size and barriers to restrict root proliferation within a patch

• Background and Aims Localized proliferation of rootsin nutrient-enriched patches seems to be an adaptive responsein many plants, but its function is still debatable. To understandthe efficiency and limitation of foraging behaviour, the impactof patch size and the presence or absence of a barrier to rootproliferation within phosphorus (P)-enriched patches was examined. • Methods In pots filled with P-poor soil, six treatmentsof heterogeneous P supply were prepared: three patch sizes withor without a root barrier between patches. In addition, a homogeneousP supply treatment was also prepared. Irrespective of thesetreatments, each pot received the same total amount of P. Maize(Zea mays) was grown in each pot for 45 d in a greenhouse. • Key Results P content and biomass were greatest in plantsgrown in the largest patch due to successful root proliferation,and were higher in the presence of a root barrier. Interestingly,plants preferentially developed adventitious nodal roots projectingfrom the stem into the P-enriched soil, particularly in thelargest patch with a root barrier. Removal of the barrier reducedthe P-uptake capacity per unit root surface area or volume inP-enriched patches, revealing that the P-uptake capacity perroot can be suppressed even in P-rich soil if other portionson the root axis encounter P-poor conditions. • Conclusions The results suggest that the efficiency ofroot morphological plasticity is largely determined by the sizeof the P-enriched patch. Furthermore, the results imply a novelaspect of P-uptake physiology that roots in heterogeneous Pcannot demonstrate their potential capacity, as would be observedin roots encountering P continuously; this effect is probablymediated by an internal root factor.     

Field Estimates of Root and Xylem Resistances in Pinus contorta using Root Excision

A root excision technique was used to estimate the proportionof total resistance to water flux residing in the soil, theroot, and the xylem of lodgepole pine (Pinus contorta Douglex. Loud.) trees in the field. Root excision at mid-day alwaysresulted in rapid recovery of leaf water potential when waterwas supplied to the cut stem, suggesting a high soil-root resistance.Transpiration was unaffected if leaf water potential beforecutting was not limiting leaf conductance. By mid-June wateruptake by the excised stem always exceeded calculated crowntranspiration indicating recharge of internal sapwood storage.Predawn leaf water potential before root excision was highlycorrelated with total soil-plant resistance (r² = 0·89)and calculated root water uptake (r² = 0·92).     

Effect of Anoxia on the Spatial Pattern of Electric Potential Formed Along the Root

Spatial patterns of surface electric potential of a root ofazuki bean (Phaseolus chrysanthos) were investigated. A multi-electrodemeasuring system was used to measure the spatial pattern andits variation with time. It was found that a periodic patternwas spontaneously formed along the root but it disappeared underanoxia. Supply of air made the pattern recover. Although thechange in electric potential started from the root tip underanoxia, it occurred first near the seed in the recovery processwhen air was supplied. To explain this phenomenon, a simplifiedtheoretical model was proposed. The model is described by adifferential equation for a concentration of oxygen expressinglongitudinal diffusion and consumption of oxygen within theroot. Assumption of a threshold of the oxygen concentrationneeded to activate a respiration-dependent pump led to a quantitativeexplanation of the above behaviour of surface electric potential.It was suggested that the pattern belongs to a group of self-organizeddynamic structures which are maintained through energy metabolismby a supply of material from outside. Phaseolus chrysanthos, bean root, electric potential, anoxia, self-organized structure, respiration-dependent pump     

Model of beta -cell mitochondrial calcium handling and electrical activity. I.Cytoplasmic variables

We continue our development of a kineticmodel of bursting electrical activity in the pancreatic -cell( J. Keizer and G. Magnus. Biophys. J. 56: 229-242,1989), including the influence of Ca²⁺ handling by themitochondria. Our minimal model of mitochondrial Ca²⁺handling [G. Magnus and J. Keizer. Am. J. Physiol. 273 (Cell Physiol. 42): C717-C733, 1997] is expanded toinclude the D-glucose dependence of the rate of productionof mitochondrial reducing equivalents. The Ca²⁺ dependenceof the mitochondrial dehydrogenases, which is also included in themodel, plays only a small role in the simulations, since thedehydrogenases appear to be maximally activated when D-glucose concentrations are sufficient to producebursting. A previous model of ionic currents in the plasma membrane isupdated using a recent experimental characterization of the dependence of the conductance of the ATP-sensitive K⁺(K_ATP) current on adenine nucleotides. The resultingwhole cell model is complex, involving 12 dynamic variables that coupleCa²⁺ handling in the cytoplasm and the mitochondria withelectrical activity in the plasma and inner mitochondrial membranes.Simulations with the whole cell model give rise to bursting electricalactivity similar to that seen in pancreatic islets and clusters ofpancreatic -cells. The full D-glucose dose response ofelectrical activity is obtained if the cytosolic rate of ATP hydrolysisis a sigmoidal function of glucose. The simulations give the correctshape, period, and phase of the associated oscillations in cytosolicCa²⁺, predict that the conductance of the K_ATPcurrent oscillates out of phase with electrical activity [as recentlyobserved in ob/ob mice (O. Larsson, H. Kindmark, R. Bränstrom, B. Fredholm, and P.-O. Berggren. Proc. Natl. Acad.Sci. USA 93: 5161-5165, 1996)], and make other novelpredictions. In this model, bursting results because Ca²⁺uptake into mitochondria during the active phase reduces the mitochondrial inner membrane potential, reducing the rate of production of ATP, which in turn activates the K_ATP current andrepolarizes the plasma membrane.

     

Influences of Water Status, Temperature, and Root Age on Daily Patterns of Root Respiration for Two Cactus Species

Daily patterns of root respiration measured as CO₂, efflux werestudied at various soil water potentials, temperatures, androot ages for individual, attached roots of the barrel cactusFerocactus acanthodes and the platyopuntia Opuntia ficus-indica.The daily patterns of root respiration for both establishedroots and rain roots followed the daily patterns of root temperature.Root respiration increased when root temperature was raisedfrom 5 °C to 50 °C for F. acanthodes and from 5 °Cto 55 °C for O. ficus-indica; at 60 °C root respirationdecreased 50° from the maximum for F. acanthodes and decreased25° for O. ficus-indica. Root respiration per unit d. wtdecreased with root age for both species, especially for rainroots. Root respiration rates for rain roots were reduced tozero at a soil water potential (     

Phenylpropanoid defence responses in transgenic Lotus corniculatus: II. Modelling plant defence responses in transgenic root cultures using thiol and carbohydrate elicitors

Transformed root cultures of Lotus corniculatus L. cv. Leo weretreated with a range of thiol and carbohydrate elicitors. Boththiol reagents and fungal carbohydrate preparations resultedin an increase in the activity of phenylalanine ammonia lyase(PAL) in a concentration-dependent manner. One representativethiol elicitor, glutathione (GSH), and one fungal elicitor,derived from Rhynchosporium orthosporum autoclaved cell walls(Ro), were analysed in more detail. Both elicitors induced thetransient accumulation of vestitol, an isoflavan phytoalexin,in tissue and in culture medium. Treatment of Lotus root cultureswith the Ro elicitor resulted in a more rapid initial accumulationof this end product when compared with GSH, however, sativan(the 2–methoxy ester of vestitol) previously reportedto co-accumulate in Lotus leaves was only detected followingelicitation with high concentrations of GSH. Ro and GSH elicitorsalso induced the accumulation of a number of other phenylpropanoidcompounds putatively identified as chalcones. The addition ofthiol and carbohydrate elicitors to Lotus root cultures alsoresulted in characteristic changes in root morphology. Glutathione,in particular, resulted in the inhibition of root growth dueto differential damage of meristem cells. Key words: Lotus corniculatus, hairy roots, elicitors, phytoalexins.     

Effects of Aqueous Extracts and Leachates of Aristida adscensionis on Indigofera cordifolia

Aqueous extracts and leachates of root, shoot, and litter ofAristida adscensionis had an inhibiting potential on the numberof root nodules in Indigofera cordifolia. The same treatmentshad a promotive effect on the dry weight of I. cordifolia.     

Nod Factor/Nitrate-Induced CLE Genes that Drive HAR1-Mediated Systemic Regulation of Nodulation

Host legumes control root nodule numbers by sensing externaland internal cues. A major external cue is soil nitrate, whereasa feedback regulatory system in which earlier formed nodulessuppress further nodulation through shoot–root communicationis an important internal cue. The latter is known as autoregulationof nodulation (AUT), and is believed to consist of two long-distancesignals: a root-derived signal that is generated in infectedroots and transmitted to the shoot; and a shoot-derived signalthat systemically inhibits nodulation. In Lotus japonicus, theleucine-rich repeat receptor-like kinase, HYPERNODULATION ABERRANTROOT FORMATION 1 (HAR1), mediates AUT and nitrate inhibitionof nodulation, and is hypothesized to recognize the root-derivedsignal. Here we identify L. japonicus CLE-Root Signal 1 (LjCLE-RS1)and LjCLE-RS2 as strong candidates for the root-derived signal.A hairy root transformation study shows that overexpressingLjCLE-RS1 and -RS2 inhibits nodulation systemically and, furthermore,that the systemic suppression depends on HAR1. Moreover, LjCLE-RS2expression is strongly up-regulated in roots by nitrate addition.Based on these findings, we propose a simple model for AUT andnitrate inhibition of nodulation mediated by LjCLE-RS1, -RS2peptides and the HAR1 receptor-like kinase.     

Increased root growth in elevated CO2: a biophysical analysis of root cell elongation

A biophysical analysis of root expansion was conducted in fourchalk downland herbs (Sanguisorba minor Scop., Lotus corniculatusL., Anthyllis vul-neraria L. and Plantago media L.) exposedto either ambient or elevated CO₂in controlled environment cabinets.Measurements of fine (F) and extra-fine (EF) root extensionrate (RER), water relations, and cell wall tensiometric extensibilityrevealed differences in the diurnal pattern of root growth betweenspecies. After 35 d of exposure to elevated CO₂, RER of bothF and EF roots increased significantly in darkness and on illuminationfor S. minor, whilst for A. vulneraria (EF roots only) and L.corniculatus a significant increase occurred at night whereasfor P. media a significant increase occurred during the day.Cells measured in the zone of elongation were longer in allspecies exposed to elevated CO₂. Water potential (     

Morphological, Anatomical and Physiological Responses Related to Differential Shoot vs. Root Growth Inhibition at Low Temperature in Spring and Winter Wheat

Several morphological, anatomical and physiological changesand their relationship with differential root vs. shoot growthinhibition at low temperature (5°C) were studied in springand winter wheat cultivars. Root:shoot ratios, expressed eitheras a function of root and shoot fresh weight or as a functionof root and leaf areas, increased at low temperature and thisincrement was more pronounced in spring cultivars than in winterones. Although winter cultivars developed relatively smallerroot systems at 5°C, this characteristic was counterbalancedby a lower stomatal frequency and increased thickness of epidermalcell walls in leaves unfolded at this temperature, relativeto spring cultivars. Likewise, at 5°C a decrease in theosmotic potential of shoots and roots was observed in parallelwith sugar accumulation; this decrease was more marked in wintercultivars. These results indicate a differential morpho-anatomicaland physiological plasticity of winter and spring cultivarsduring development at low temperature. The possible associationbetween these changes and plant water economy at low temperaturesis discussed. Copyright 2001 Annals of Botany Company Spring wheat, winter wheat, Triticum aestivum, low temperature, root:shoot ratio, root surface area, stomatal frequency, osmotic potential     

The Vascular Pattern of a Rhizomatous Ginger (Alpinia speciosa L. Zingiberaceae). 2. The Rhizome

The vascular system in the underground rhizome of Alpinia speciosaL. (Zingiberaceae) is seen to be arranged in three distinctzones. (1) An inner system of ‘scattered’ vascularbundles which serial cinematography reveals to have an axialpattern conforming to the basic ‘palm’ configuration(a system of upwardly branching leaf traces with interconnections).(2) An intermediate zone comprising a thin perforated cylinderof anastomosing vascular strands having direct contact withboth roots and inner system bundles. (3) An outer system offreely-anastomosing vascular bundles. Connexion of outer andinner system occurs in the form of extensive bridging from innersystem leaf traces as they depart obliquely between the outersystem network. The interrelation of the three systems, plus root and branchinsertion, is illustrated by means of diagrammatic three-dimensionalreconstructions. The intermediate zone is intimately associatedwith root insertions and with the inner system, and is shownto obliviate potential bottlenecks at the point of lateral branchinsertion in this sympodial rhizome system. A comparison ismade with other monocotyle-donous vascular systems. Alpinia speciosa L., shell ginger, rhizome, vascular anatomy     

Different modes of sodium-D-glucose cotransporter-mediated D-glucose uptake regulation in Caco-2 cells

We recently reported that a considerable amount of the sodium-D-glucose cotransporter SGLT1 present in Caco-2 cells, a model for human enterocytes, is located in intracellular compartments attached to microtubules (Kipp H, Khoursandi S, Scharlau D, and Kinne RKH. Am J Physiol Cell Physiol 285: C737–C749, 2003). A similar distribution pattern was also observed in enterocytes in thin sections from human jejunum, highlighting the validity of the Caco-2 cell model. Fluorescent surface labeling of live Caco-2 cells revealed that the intracellular compartments containing SGLT1 were accessible by endocytosis. To elucidate the role of endosomal SGLT1 in the regulation of sodium-dependent D-glucose uptake into enterocytes, we compared SGLT1-mediated D-glucose uptake into Caco-2 cells with the subcellular distribution of SGLT1 after challenging the cells with different stimuli. Incubation (90 min) of Caco-2 cells with mastoparan (50 µM), a drug that enhances apical endocytosis, shifted a large amount of SGLT1 from the apical membrane to intracellular sites and significantly reduced sodium-dependent -[¹⁴C]methyl-D-glucose uptake (–60%). We also investigated the effect of altered extracellular D-glucose levels. Cells preincubated (1 h) with D-glucose-free medium exhibited significantly higher sodium-dependent -[¹⁴C]methyl-D-glucose uptake (+45%) than did cells preincubated with high D-glucose medium (100 mM, 1 h). Interestingly, regulation of SGLT1-mediated D-glucose uptake into Caco-2 cells by extracellular D-glucose levels occurred without redistribution of cellular SGLT1. These data suggest that, pharmacologically, D-glucose uptake can be regulated by a shift of SGLT1 between the plasma membrane and the endosomal pool; however, regulation by the physiological substrate D-glucose can be explained only by an alternative mechanism. endosomes; enterocytes     

Effects of Acetylene and External Oxygen Concentration on the Respiratory Quotient (RQ) of Nodulated Roots of Soyabean and White Clover

Carbon dioxide output and oxygen uptake by intact nodulatedroots of soyabean and white clover were determined over a rangeof external oxygen concentrations (10 to 60%) in the presenceand absence of 10% acetylene. The responses of both sets ofroot systems were in agreement with the known characteristicsof the variable oxygen diffusion resistance of the nodules.These measurements were used to calculate the respiratory quotient(RQ, CO2/O2) for both total root respiration and nitrogenase-linkedrespiration values for each external oxygen concentration. Inthe absence of acetylene, the RQ values of soyabean total rootrespiration showed no significant response to external oxygen,with a mean of 1.06, but differences in values for white cloverroots were significant at P=0.05, with a mean of 1.09. The sametrend was shown for RQ values of nitrogenase-linked respiration,with mean values of 1.10 and 1.12 for soyabean and clover, respectively.The addition of acetylene caused a small but significant initialreduction in RQ of total root respiration with both soyabeanand white clover, as did the subsequent reduction of externaloxygen to 10%. For white clover, increases in external oxygenconcentration to 50% and 60% also produced significant increasesin the RQ of total root respiration compared to that in air.These variations were more pronounced for RQ values of nitrogenaselinkedrespiration. Results are discussed in relation to the use ofRQ values of unity in calculations of nodular oxygen diffusionresistance and the involvement of physical and biochemical processesin the regulation of oxygen supply to bacteroids. Key words: Respiratory quotient, nodules, oxygen, diffusion resistance     

Internal Root Anatomy of Maize Seedlings (Zea mays L.) as Influenced by Temperature and Genotype

The objectives of this investigation were to determine: (a)the general effect of temperature on internal root anatomy;(b) whether genotypic differences in such root traits exist;and (c) the association between internal root traits and shootgrowth, lateral root branching and cold tolerance of maize (Zeamays L.). Seedlings of 20 central European hybrids were grownunder high or low temperature (25/22·5 °C or 15/12·5°C day/night temperatures) until the third leaf was fullyexpanded. Light microscopy of cross sections revealed a largerdiameter of primary roots at low temperature which was due toa larger stele diameter and a thickening of the cortex. Concurrently,an increase in total cross sectional area of metaxylem elementswas obtained. It is assumed that the modification of the internalroot structure by temperature has an effect on both axial andradial water flow capacity. For all anatomical traits studied,variability between genotypes was apparent under both growingconditions. Furthermore, different genotypic responses to temperaturewere observed. However, basic differences between cold-tolerantand cold-sensitive genotypes did not exist. While at high temperatureroot traits and shoot growth were significantly and positivelycorrelated, at low temperature the correlation coefficient wasinsignificant. Consequently, it was not possible to characterizethe performance of the shoot at low temperature based on anatomicaltraits of the root. Moderate, positive correlation coefficientswere obtained between internal root traits and lateral rootbranching. The potential use of root anatomical traits as indirectselection criteria is discussed. Chilling tolerance, genotypes, root anatomy, Zea mays L