Changes in Cell Membrane Permeability in Sunflower Hypocotyls Infected with Sclerotinia sclerotiorum

Influx and efflux of water and urea and electrolyte leakage are less for sunflower (Helianthus annuus) hypocotyl sections above lesions caused by Sclerotinia sclerotiorum than for those from healthy plants. Urea uptake by sections above lesions is reduced (celery, squash, and tomato) or unchanged (bean) in other hosts after Sclerotinia infection. Efflux of urea from sunflower hypocotyls is biphasic, suggesting diffusion in series from two cellular compartments (cytoplasm and vacuole). Efflux during the fast phase was 7 to 20 times greater than that during the slow phase. No difference was noted in urea efflux from healthy and diseased tissues during the slow phase. However, efflux during the fast phase from diseased tissues was slower than from healthy tissues, suggesting that the increased resistance to diffusion of urea in host cells above lesions resides in the plasmalemma. Water movement across cell membranes of healthy and diseased sunflower hypocotyls was reduced when tissues were treated with p-hydroxymercuribenzoate.     

Uptake of 3-o-Methylglucose by Healthy and Hypomyces-infected Squash Hypocotyls

Rates of uptake of 3-o-methylglucose (MeG) by squash (Cucurbita maxima) hypocotyl sections from above lesions caused by Hypomyces solani f. sp. cucurbitae, race 1, are 2-fold greater than uptake by comparable tissues from healthy plants. Kinetic analyses indicate (i) that a single (constitutive) carrier system, with a Michaelis constant (Km) of 25 to 30 mm, mediates the transport of MeG into healthy hypocotyl cells and (ii) that an additional (inducible) system with a much lower Km (ca. 2 mm) is present in diseased hypocotyls. In both systems MeG uptake is inhibited competitively by glucose. The inducible transport system (s) in diseased tissues has a higher temperature coefficient, greater sensitivity to metabolic inhibitors and larger accumulation capacity than the one in healthy plants. While the nature of the constitutive system is ambiguous, the inducible carrier mechanism is a typical active transport system. These results indicate that increased rates of uptake and accumulation of metabolites by diseased tissues can be caused by new transport systems.     

Cytohistochemical techniques for calcium localization and their application to diseased plants

Lesion delimitation and resistance of old bean (Phaselous vulgaris L., cv. Red Kidney) plants to Rhizoctonia solani Kühn have been suggested to result from increased calcium pectate formation in walls. Ultrastructural histochemistry was used to determine the site of calcium in tissues adjacent to lesions and in older bean hypocotyls. Hypocotyl lesion tissue and uninoculated control tissue were treated with ammonium oxalate or potassium pyroantimonate during fixation. Treatment with potassium pyroantimonate, but not with oxalate, resulted in granular deposits in cell walls of healthy and lesion tissue. Granules also occurred on the plasma membrane of cells adjacent to lesions and in organelles of damaged cells, but wall granule density was not increased. Cell walls from healthy 24-day-old plants had a greater granule density than those for 8-day-old plants. Wall granules were removed from thin sections with ethylene glycol bis(β-aminoethyl ether)-N,N,N′,N′-tetraacetic acid. Energy dispersive analysis of x-rays also suggested that potassium pyroantimonate localized calcium. Chemical analyses showed that some calcium was retained in tissues after fixation. The results suggest that there are different mechanisms for lesion delimitation and age-induced resistance.     

Permeability Characteristics and Amino Acid Incorporation during Senescence (Ripening) of Banana Tissue

Changes in free space of banana tissue during ripening were measured using radioisotopes. Free space increased significantly about 44 hours before the onset of, and rose exponentially during the respiratory climacteric. The increase in free space indicates a progressive increase in the proportion of cells which becomes completely permeable to solutes in the ambient solution by simple diffusion. At the respiratory peak the tissue was essentially 100% free space to mannitol, sucrose, fructose and chloride.

The capacity for active uptake of solutes declined about one day before the onset of the respiratory rise and fell to a very low level by the respiratory peak.

There was no change in the level of protein or amino acids during ripening. Assays of tissue sections before and after washing indicated an increased rate of leakage of amino acids during ripening.

Studies of incorporation of 3 concentrations of ¹⁴C-labeled leucine and phenylalanine indicated marked changes in the size and specific activity of the amino acid pool at the site of protein synthesis just prior to and during the climacteric rise, due to a diffusive mixing of the labeled substrate with the previously sequestered endogenous, unlabeled pool of substrate. The use of a high concentration of exogenous substrate (above saturation for uptake) resulted in an apparent constant specific activity of the metabolic pool through the ripening period. Data from these studies indicated a decline in amino acid incorporation during the climacteric.

It was concluded that the initiation of permeability changes marks the onset of senescence in banana. The causative relations between alterations in permeability, the respiratory rise and other chemical changes attending fruit ripening are discussed.

     

Plant Desiccation and Protein Synthesis. IV. RNA Synthesis, Stability, and Recruitment of RNA into Protein Synthesis during Desiccation and Rehydration of the Desiccation-Tolerant Moss, Tortula ruralis

We have studied the effects of ATP and ADP on the oxidation of malate by coupled and uncoupled mitochondria prepared from etiolated hypocotyls of mung bean (Vigna radiata L.).

In coupled mitochondria, ATP (1 millimolar) increased pyruvate production and decreased oxaloacetate formation without altering the rate of oxygen consumption. ATP also significantly decreased oxaloacetate production and increased pyruvate production in mitochondria that were uncoupled by carbonyl cyanide p-trifluoromethoxyphenyl hydrazone plus oligomycin.

In coupled mitochondria, ADP (1 millimolar) increased the production of both pyruvate and oxaloacetate concomitantly with the acceleration of oxygen uptake to the state 3 rate. The effects of ADP were largely eliminated in uncoupled mitochondria. These results indicate that, whereas the ADP stimulation of oxaloacetate and pyruvate production in the coupled mitochondria is brought about primarily as the result of the accelerated rates of electron transport and NADH oxidation by the respiratory chain in state 3, ATP has significant regulatory effects independent of those that might be exerted by control of electron transport.

     

Studies on Genetic Male-Sterile Soybeans : IV. Effect of Male Sterility and Source of Nitrogen Nutrition on Accumulation, Partitioning, and Transport of Nitrogen

Soybean (Glycine max [L.] Merr.) germplasm, isogenic except for loci controlling male sterility (ms₁) and nodulation (rj₁), was used to investigate the effects of reproductive tissue development and source of nitrogen nutrition on accumulation, transport, and partitioning of nitrogen in a greenhouse experiment. Nodulated plants were supplied nitrogen-free nutrient solution, and nonnodulated plants were supplied nutrient solution containing 20 millimolar KNO₃. Plants were sampled from flowering until maturity (77 to 147 days after transplanting).

Accumulation rates of nitrogen in whole plants during reproductive growth were not significantly different among the four plant types. Nitrogen accumulation in the sterile, nonnodulated plants, however, ceased 2 weeks earlier than in fertile, nonnodulated or fertile and sterile, nodulated plants. This early cessation in nitrogen accumulation resulted in sterile, nonnodulated plants accumulating significantly less whole plant nitrogen by 133 days after transplanting (DAT) than fertile, nonnodulated plants. Thus, changing the site of nitrogen assimilation from nodules (N₂-fixing plants) to roots and leaves (NO₃-fed plants) resulted in similar whole-plant nitrogen accumulation rates in fertile and sterile plants, despite the absence of seed in the latter.

Leaflet and stem plus petiole tissues of both types of sterile plants had significantly higher nitrogen concentrations after 119 DAT than both types of fertile plants. Significantly higher concentrations and exudation rates of nonureide, reduced-nitrogen in xylem sap of sterile than of fertile plants after 105 DAT were observed. These latter results indicated possible cycling of nonureide, reduced-nitrogen from the downward phloem translocation stream to the upward xylem translocation stream in roots of sterile plants. Collectively, these results suggest a lack of sinks for nitrogen utilization in the shoots of sterile plants. Hence, comparison of nitrogen accumulation rates for sterile and fertile plants does not provide a definitive test of the hypothesis that reproductive tissue development limits photosynthate availability for support of N₂ fixation and nitrate assimilation in determinate soybeans.

Nitrogen assimilation during reproductive growth met a larger proportion of the reproductive-tissue nitrogen requirement of nitrate-dependent plants (73%) than of N₂-fixing plants (63%). Hence, vegetative-tissue nitrogen mobilization to reproductive tissue was a more prominent process in N₂-fixing than in nitrate-dependent plants. N₂-fixing plants partitioned nitrogen to reproductive tissue more efficiently than nitrate-dependent plants as the reproductive tissues of the former and latter contained 65 and 55%, respectively, of the whole-plant nitrogen at the time that nitrogen accumulation in reproductive parts had ceased (133 DAT).

     

Sodium relations in Chenopodiaceae: a comparative approach

Sodium relations of 15 species of Chenopodiaceae were studied in seedlings grown on quartz sand at 10 mol m^?3 of sodium and potassium. Uptake of sodium and potassium into whole plants and shoots was followed over 2 weeks. High alkali ion uptake rates were found in all species. The apparent selectivity of alkali ion uptake showed a continuous variation between species, from nearly perfect sodium exclusion to negligible cation selection. K/Na ratios above 6 were found in the shoots of eight species. For most of these plants above ground sodium concentrations were highest in the hypocotyls. However, in Chenopodium hybridum (shoot K/Na = 10) and C. urbicum (shoot K/Na = 17) above ground sodium concentrations were lowest in hypocotyls and highest in leaves, as in those species accumulating larger amounts of sodium. These differences are discussed with respect to the underlying mechanisms of ion regulation.     

Insensitivity of the diageotropica tomato mutant to auxin

The sensitivity of excised hypocotyl segments to indoleacetic acid (IAA) in two assays, ethylene production and elongation, was determined in the ethylene-requiring tomato (Lycopersicon esculentum Mill.) mutant, diageotropica (dgt), and its isogenic parent, cv VFN8. Endogenous (uninduced) ethylene synthesis rates were slightly lower in dgt hypocotyls than in VFN8 hypocotyls. Ethylene production was essentially unaffected by IAA in dgt, but was stimulated up to 10-fold by 10 micromolar IAA in VFN8. Elongation of dgt hypocotyls was also insensitive to concentrations of IAA as high as 100 micromolar, as compared to significant elongation of VFN8 hypocotyls in response to 0.1 micromolar IAA. A range of IAA analogs active in VFN8 was also ineffective in stimulating elongation of dgt hypocotyls, suggesting that the differences were not due to rapid metabolism of IAA by dgt tissues. Auxin-induced elongation of VFN8 hypocotyls was unaffected by 2,3,5-triiodobenzoic acid and naphthylphthalamic acid, indicating that polar auxin transport was not a factor in these experiments. Exogenous and auxin-induced ethylene had no effect on the elongation respone of either genotype, nor did exogenous ethylene restore the sensitivity of dgt hypocotyls to IAA. Despite their apparent insensitivity to auxin, dgt hypocotyls elongated dramatically and synthesized ethylene rapidly in response to 1.2 micromolar fusicoccin. These results suggest that the primary effect of the dgt mutation is to reduce the sensitivity of the tissue to auxin. As altered regulation of ethylene synthesis is only one symptom of this fundamental deficiency, dgt should more properly be considered to be the auxin-insensitive tomato mutant.     

Solutes in the free space of growing stem tissues

The concentration of osmotically active solutes in the cell wall free space of young stem tissues was studied using a variety of extraction methods. When the intercellular air spaces of etiolated pea (Pisum sativum L.) internodes were perfused with distilled H₂O, the resulting solution contained a solute concentration of about 70 milliosmoles per kilogram. A second procedure involving vacuum infiltration of segments followed by centrifugation to collect the free space solution gave similar results. Apical stem segments yielded free space extracts about twice as concentrated as those from basal portions of the stem. After correcting for dilution of the free space solution by the infiltrated water, the osmotic pressure of the undiluted free space in pea stem tissue was estimated to be 2.9 bars for apical segments, 1.8 bars for basal regions. These values may be somewhat overestimated due to solute efflux from intracellular pools during the extraction procedure. Similar results were obtained for stem regions of etiolated soybean (Glycine max [L.] Merr.) and cucumber (Cucumis sativus L.) seedlings.

From measurements of the electrical conductivity and refractive index of free space extracts before and after ashing, it appears that 25% of the solutes are inorganic electrolytes and 75% are organic nonelectrolytes with an average size similar to that of glucose.

A significant osmotic pressure in the wall space offers an explanation for the frequent observation that nontranspiring plants have negative water potentials. Calculations of hydraulic resistance from water potential data must take into account solutes in the free space, else `apparent,' but unreal, changes in resistance may be calculated.

     

Effect of butanedioic Acid mono (2,2-dimethylhydrazide) on the activity of membrane-bound succinate dehydrogenase

Mitochondria isolated from hypocotyls of five-day-old bean (Phaseolus vulgaris L. `Black Valentine') seedlings rapidly oxidized succinate, malate, and NADH. Oxidation rates, respiratory control, and ADP:O ratios obtained with saturating concentrations of all three substrates indicated that the mitochondria were tightly coupled. The mitochondrial preparation was then employed to investigate the respiration-inhibiting effects of butanedioic acid mono (2,2-dimethyl-hydrazide) (daminozide) a plant growth retardant having structural similarity to an endogenous respiratory substrate (succinate). Daminozide markedly inhibited the activity of membrane-bound succinate dehydrogenase. Inhibition was of the competitive type (apparent K_i, 20.2 millimolar) with respect to succinate. Although not excluding other hypotheses, the results support an active role for daminozide in the suppression of respiration as an important metabolic site of its action as a plant growth regulator.     

Biochemical Bases for the Loss of Basipetal IAA Transport with Advancing Physiological Age in Etiolated Helianthus Hypocotyls: Changes in IAA Movement, Net IAA Uptake, and Phytotropin Binding

Basipetal transport of [¹⁴C]IAA in hypocotyl segments isolated from various regions of etiolated Helianthus annuus L. cv NK 265 seedlings declines with increasing physiological age. This decline was the result of a reduction in both transport capacity and apparent velocity. Net IAA uptake was greater and the abilities of auxin transport inhibitors to stimulate net IAA uptake were reduced in older tissues. Net IAA accumulation by microsomal vesicles exhibited a similar behavior with respect to age. Specific binding of [³H]N-1-naphthylphthalamic acid (NPA) to microsomes prepared from young and older hypocotyl regions was saturable and consistent with a single class of binding sites. The apparent affinity constants for NPA binding in microsomes prepared from young versus older tissues were 6.4 and 10.8 nanomolar, respectively, and the binding site densities for young versus old tissues were 7.44 and 3.29 picomoles/milligram protein, respectively. Specific binding of [³H]NPA in microsomes prepared from both tissues displayed similar sensitivities toward unlabeled flurenol and exhibited only slight differences in sensitivity toward 2,3,5-triiodobenzoic acid. These results demonstrate that the progressive loss of basipetal IAA transport capacity in etiolated Helianthus hypocotyls with advancing age is associated with substantial alterations in the phytotropin-sensitive, IAA efflux system and they suggest that these changes are, at least partially, responsible for the observed reduction of polar IAA transport with advancing tissue age.     

Gravitropism in Higher Plant Shoots : VI. Changing Sensitivity to Auxin in Gravistimulated Soybean Hypocotyls

Although the Cholodny-Went model of auxin redistribution has been used to explain the transduction phase of gravitropism for over 60 years, problems are apparent, especially with dicot stems. An alternative to an auxin gradient is a physiological gradient in which lower tissues of a horizontal stem become more sensitive than upper tissues to auxin already present. Changes in tissue sensitivity to auxin were tested by immersing marked Glycine max Merrill (soybean) hypocotyl sections in buffered auxin solutions (0, 10⁻⁸ to 10⁻² molar indoleacetic acid) and observing bending and growth of upper and lower surfaces. The two surfaces of horizontal hypocotyl sections responded differently to the same applied auxin stimulus; hypocotyls bent up (lower half grew more) in buffer alone or in low auxin levels, but bent down (upper half grew more) in high auxin. Dose-response curves were evaluated with Michaelis-Menten kinetics, with auxin-receptor binding analogous to enzyme-substrate binding. V_max for the lower half was usually greater than that for the upper half, which could indicate more binding sites in the lower half. K_m of the upper half was always greater than that of the lower half (unmeasurably low), which could indicate that upper-half binding sites had a much lower affinity for auxin than lower-half sites. Dose-response curves were also obtained for sections `scrubbed' (cuticle abraded) on top or bottom before immersion in auxin, and `gravitropic memory' experiments of L. Brauner and A. Hagar (1958 Planta 51: 115-147) were duplicated. [1-¹⁴C]Indoleacetic acid penetration was equal into the two halves, and endogenous plus exogenously supplied (not radiolabeled) free auxin in the two halves (by gas chromatography-selected ion monitoring-mass spectrometry) was also equal. Thus, differential growth occurred without free auxin redistribution, contrary to Cholodny-Went but in agreement with a sensitivity model.     

Tissue-specific localization of an abscisic acid biosynthetic enzyme, AAO3, in Arabidopsis

Arabidopsis aldehyde oxidase 3 (AAO3) is an enzyme involved in abscisic acid (ABA) biosynthesis in response to drought stress. Since the enzyme catalyzes the last step of the pathway, ABA production sites may be determined by the presence of AAO3. Here, AAO3 localization was investigated using AAO3 promoter:AAO3-GFP transgenic plants and by an immunohistochemical technique. AAO3-GFP protein exhibited an activity to produce ABA from abscisic aldehyde, and the transgene restored the wilty phenotype of the aao3 mutant. GFP-fluorescence was detected in the root tips, vascular bundles of roots, hypocotyls and inflorescence stems, and along the leaf veins. Intense immunofluorescence signals were localized in phloem companion cells and xylem parenchyma cells. Faint but significant GFP- and immuno-fluorescence signals were observed in the leaf guard cells. In situ hybridization with antisense AAO3 mRNA showed AAO3 mRNA expression in the guard cells of dehydrated leaves. These results indicate that the ABA synthesized in vascular systems is transported to various target tissues and cells, and also that the guard cells themselves are able to synthesize ABA.     

Phototropism in Hypocotyls of Radish: IV. Flank Growth and Lateral Distribution of cis- and trans-Raphanusanins in the First Positive Phototropic Curvature

The first positive phototropic curvature induced by a pulse of unilateral white irradiation (0.1 watt per square meter, 30 seconds) of etiolated and de-etiolated Sakurajima radish (Raphanus sativus var hortensis f. gigantissimus Makino) hypocotyls was analyzed in terms of differential growth and growth inhibitor contents of the hypocotyls. In both etiolated and de-etiolated hypocotyls, the growth rates at the lighted sides were suppressed whereas those at the shaded ones showed no change. De-etiolation treatment induced a larger difference between the growth rates at the lighted and shaded sides of the hypocotyls, resulting in a larger curvature of de-etiolated seedlings than of etiolated ones. The contents of growth inhibitors, cis- and trans-raphanusanins, increased in the lighted but not in the shaded halves of the hypocotyls of etiolated seedlings. In de-etiolated seedlings, the two inhibitors increased due to the de-etiolation treatment. When de-etiolated seedlings were exposed to a pulse of unilateral irradiation the level of the two inhibitors remained high along the lighted side for 1 h following the light pulse, whereas at the shaded side the contents of the inhibitors abruptly decreased upon transfer to the dark, the difference between their amounts in the lighted and shaded sides being larger than in etiolated seedlings. Another growth inhibitor, raphanusamide, did not respond to the phototropic stimulus, although its amounts increased by the de-etiolation treatment. These data suggest that cis- and trans-raphanusanins are involved in the first positive phototropic response of radish hypocotyls, and that de-etiolation magnifies the phototropic response through induction of a larger lateral gradient of the raphanusanins in the hypocotyls by the phototropic stimulus.     

Host-Pathogen Interactions: VIII. Isolation of a Pathogen-synthesized Fraction Rich in Glucan That Elicits a Defense Response in the Pathogen's Host

A polysaccharide from the fungal pathogen Colletotrichum lindemuthianum causes browning and phytoalexin production when applied to the cut surfaces of bean (Phaseolus vulgaris) cotyledons and hypocotyls. The application of an amount of polysaccharide equivalent to less than 100 ng of glucose will elicit this response in the bean tissues. The polysaccharide has been isolated both from culture filtrates and from the mycelial walls of the fungus. Purification of the polysaccharide involved anion and cation exchange chromatography and gel filtration. The polysaccharide has an apparent molecular weight between 1,000,000 and 5,000,000 daltons, and consists predominantly of 3- and 4-linked glucosyl residues.     

Patterns of transformation intensity on flax hypocotyls inoculated with Agrobacterium tumefaciens

Summary Cellular transformation intensities on flax (Linum usitatissimum) hypocotyl explants using disarmed Agrobacterium tumefaciens were investigated through various preculture durations, cocultivation durations and removal of epidermis. The expression of an intron-containing -glucuronidase (GUS) gene driven by CaMV 35S promoter served as a reporter for determination of transformed tissues on hypocotyls. The binary plasmid p35SGUSINT in octopine-type Agrobacterium strain GV2260 was used as the vector system. A prolonged cocultivation duration (5–7 days) resulted in a much higher transformation staining intensity (frequency * tissue area) than 2- or 3-day-cocultivation duration on hypocotyls variously precultured prior to inoculation. A high staining intensity on the two cut ends was obtained from nonprecultured hypocotyls. A reduction in intensity on the upper cut end of hypocotyls was observed with preculture times greater than 6 days. Peeled hypocotyls with a post-peeling preculture of 2 or 3 days had a high proportion of superficial area covered by transformed tissues after a 7 day-cocultivation duration. These results will help to improve the efficiency of recovery of transgenic plants by increasing the proportion of transformation in the regenerable tissues.     

Boron-regulated hypocotyl elongation is affected in Arabidopsis mutants with defects in light signalling pathways

We studied the effect of elevated boron (B) concentrations on the growth and development of Arabidopsis thaliana in vitro with respect to different light conditions. Two basic responses were observed. At high concentrations (above 5 mM) a clear toxicity effect of B on plant growth was apparent. Seedlings were short, stunted and pale. However at concentrations between 1 and 3 mM H₃BO₃, hypocotyl elongation was stimulated in all Arabidopsis ecotypes tested relative to plants grown at 0.1 mM H₃BO₃. The stimulation of hypocotyl elongation by elevated B was proportionally greater with increasing irradiance. We also showed that blue light (BL) and red light (RL) did not alter the sensitivity of Arabidopsis hypocotyls to boron, but, dependent on genotype, BL and RL increased or reduced capacity of boron-induced hypocotyl elongation. Analysis of photomorphogenic mutants indicated the existence of an interaction between boron and light signalling pathways during plant growth and development. This interaction was supported by the observation that the expression of the BOR1 gene in Arabidopsis hypocotyls was stimulated by BL and RL. Our results suggest that in etiolated or light-grown seedlings the stimulation of hypocotyl growth by boron can be mediated by cryptochromes and phytochromes.     

Distribution of Lectins in the Jumbo Virginia and Spanish Varieties of the Peanut, Arachis hypogaea L

Peanut lectin was purified from seed meal of the Spanish and Jumbo Virginia varieties of peanut (Arachis hypogaea L.) by affinity chromatography on lactose coupled to Sepharose 4B. Polyacrylamide gel isoelectric focusing resolved the lectin preparation from Jumbo Virginia seeds into seven isolectins (pI 5.7, 5.9, 6.0, 6.2, 6.3, 6.5, and 6.7). Seed meal from the Spanish variety contained six isolectins which were indistinguishable from the pI 5.7, 5.9, 6.2, 6.3, 6.5, and 6.7 isolectins from Jumbo Virginia. Quantitative, lactose-specific hemagglutination was used to examine the lectins in tissues of both peanut varieties. In young (3- to 9-day-old) seedlings of each variety, more than 90% of the total amount of lectins detected in the plants was in the cotyledons. Most of the remainder was in hypocotyls, stems, and leaves; young roots contained no more than 4 micrograms of lectin per plant. Lectins were present in all nonroot tissues of 21- to 30-day-old seedlings, except 27-day-old Spanish hypocotyls. As cotyledons of each variety senesced, several of the more basic isolectins decreased to undetectable levels, but the acidic isolectins remained until at least 15 days after planting. Some of the seed isolectins and several apparently new lactose-binding lectins were also identified in affinity-purified extracts of 5-day-old roots and hypocotyls. Rabbit antibodies raised against the Jumbo Virginia seed isolectin preparation reacted with seed, cotyledon, and hypocotyl lectin preparations from both varieties. Analysis of seed lectin preparations from seven varieties of A. hypogaea and of a related species (A. villosulicarpa) indicated that isolectin composition in Arachis may be a characteristic of both the species and the subspecies (botanical type) to which the variety belongs.     

Changes in the metabolome and histopathology of Amaranthus hypochondriacus L. in response to Ageratum enation virus infection

Amaranthus hypochondriacus L. infected with Ageratum enation virus (AEV) was investigated for identifying alteration in the anatomical structures, sap translocation and metabolomic variations using light microscopy, magnetic resonance imaging, NMR spectroscopy and GC–MS, respectively. Combination of GC–MS and NMR spectroscopy identified 68 polar and non-polar metabolites that were present in different levels in healthy and virus-infected A. hypochondriacus. Contrast of T₁ and T₂ weighted MR images showed significant differences in the spatial distribution of water, lipids and macromolecules indicating alterations in the cortical region and disruption of vascular bundles in virus-infected stem tissues. MRI observations are supported by light microscopic examination. Microscopic examination of AEV infected stem revealed severe hyperplasia with a considerable reduction in size of stem cells. The NMR spectroscopy and GC–MS analysis indicated that viral infection significantly affected the plant primary and secondary metabolism resulting in decreased glucose and sucrose content and increase in the concentration of β-sitosterol and stigmasterol. Higher accumulation of TCA cycle intermediates such as citric acid and malic acid in AEV infected plants indicated enhanced rate of respiratory metabolism. The viral stress significantly increases the concentration of erythritol and myo-inositol as compared to healthy ones. Lower concentration of glucose and sucrose in viral-infected stem tissues suggests decreased translocation of photosynthates in the plants. The results demonstrated potential of MRI, NMR spectroscopy and GC–MS for studying anatomical and metabolic variations in virus-infected plants.     

The Effects of Temperature on the Respiratory Responses of Groundsel (Senecio vulgaris) to Infection by Rust (Puccinia lagenophorae)

Groundsel (Senecio vulgaris) was grown in either a warm (20°C) or a cool (8°C) controlled environment and infected with Puccinia lagenophorae. Dark respiration, measured over the range 6 to 18°C, was higher in leaves of healthy plants grown under low temperatures than in those of plants grown under high temperatures. Infection increased the rates of dark respiration in the region of sporulating lesions in both sets of plants, but the greater increase in plants grown under warm conditions resulted in both sets having similar respiration rates across the range 6 to 18°C. The conclusion that the magnitude of the respiratory increase following rust infection depends upon the conditions under which plants were grown is supported by literature on other rust diseases and has implications for the utilization of carbohydrate reserves and the survival of both rust and host populations over winter.