Plant- and stimulus-specific variations in remote-controlled sieve-tube occlusion

Phloem injury triggers local sieve-plate occlusion including callose-mediated constriction and protein plugging of sieve pores. In intact plants, reversible sieve-plate occlusion is induced by electric potential waves (EPWs)—accompanied by Ca²⁺-influx—as result of distant burning. Here, we present additional results which pertain to (a) the variability of EPW-profiles in relation to forisome conformation in intact Vicia faba plants and (b) the differential occlusion reactions to burning and cutting in various plant species. A correlation between stimulus perception and mode of phloem loading is discussed.Key words: callose, electrical potential waves, forisome, membrane potential, phloem transport, sieve-element occlusion, wound potentials     

Induction as well as suppression: How aphid saliva may exert opposite effects on plant defense

Aphids ingest from the sieve tubes and by doing so they are confronted with sieve-tube occlusion mechanisms, which are part of the plant defense system. Because aphids are able to feed over longer periods, they must be able to prevent occlusion of the sieve plates induced by stylet penetration. Occlusion probably depends upon Ca²⁺-influx into the sieve element (SE) lumen. Aphid behavior, biochemical tests and in vitro experiments demonstrated that aphid''s watery saliva, injected during initial phase of a stylet penetration into the SE lumen, contains proteins that are able to bind calcium and prevent calcium-induced SE occlusion. In this addendum, we speculate on the consequences of saliva secretion for plant resistance. (a) The release of elicitors (e.g., oligogalacturonides) due to cell wall digestion by gel saliva enzymes may increase the resistance of cortex, phloem parenchyma cells and companion cells (CC) around the puncture site. (b) Ca²⁺-binding by aphid watery saliva may suppress the local defense responses in the SEs. (c) Signaling cascades triggered in CCs may lead to systemic resistance.Key words: aphid saliva, calcium binding, elicitor, oligogalacturonides, local plant defense, systemic plant defense, phloem translocation, aphid/plant-interactionAfter having penetrated the sieve-element (SE) plasma membrane, aphids encounter unspecific wound-induced occlusion reactions to prevent sap leakage.^1–4 Occlusion mechanisms by callose, structural P-proteins and forisomes are likely induced by a sudden calcium influx into the sieve-tube lumen.⁵ Calcium possibly enters the sieve-tube lumen through the stylet wounding-site in the plasma membrane and/or stretch-activated calcium-channels.^6–8 After SE penetration, aphids secrete watery saliva that contains calcium-binding proteins presumed to sabotage sieve-plate occlusion.^9,10We demonstrated that Megoura viciae (Buckton) is most likely able to prevent or reduce sieve-tube occlusion in Vicia faba by secretion of watery saliva. By in vitro confrontation of isolated forisomes, protein bodies responsible for sieve-tube occlusion in Fabaceaen,⁵ and watery saliva concentrate, we were able to show that salivary proteins convey forisomes from a dispersed (+Ca²⁺) into a condensed (−Ca²⁺) state.¹⁰ The dispersed forisome functions in vivo as a plug, leading to stoppage of mass flow.⁵This in vitro evidence was corroborated by aphid behavior in response to leaf tip burning, which triggers an electrical potential wave (EPW) along the sieve tubes. Such an EPW induces Ca²⁺-influx and corresponding SE occlusion along the pathway.¹¹ The passage of the EPW is associated with a prolonged secretion of watery saliva of aphids. This is interpreted as an attempt to unplug the SEs by calcium binding.¹⁰ Similar behavioral changes in response to leaf-tip burning were observed in an extended set of aphid/plant species combinations, indicating that attempted sabotage of sieve-tube occlusion by aphid saliva is a widespread phenomenon (unpublished).Aphid feeding was reported to induce local (on the same leaf) and systemic (in distant leaves) reactions of the host plant. The local response led to enhanced feeding,^12–14 while the systemic response showed reduced ingestion and extended periods of watery saliva secretion in sieve tubes distant from previous feeding sites.^12–14 These contrasting observations were described to be independent of the aphid species.¹³ The question arises how aphids induce these seemingly opposite plant responses?The aphid stylet pushing forward through cortical and vascular tissue is surrounded by a sheath of gel saliva, secreted into the apoplast.^15,16 Gel saliva contains cellulase and pectinase that amongst others produce oligogalacturonides (OGs) along the stylet sheath by digestion of cell wall material.^17,18 Usually, OGs act as elicitors, triggering a variety of plant responses against pathogens and insects in which the activation of calcium channels is involved.^19,20 This seems to conflict with a suppression of resistance as observed for the impact of watery saliva in SEs.¹⁰ We will make an attempt to explain this paradoxon.OG induced defense responses may be triggered in all cell types adjacent to the salivary sheath (Fig. 1). Because watery saliva is only secreted briefly into these cells, which are punctured for orientation purposes (Hewer et al., unpublished), it seems unlikely that OG induced defense is suppressed here by saliva-mediated calcium binding.¹⁵ The diffusion range of OGs may be restricted to the close vicinity of the stylet sheath leading to an enhanced regional defense with a limited sphere of action (Fig. 1). Because the settling distance of aphids is restricted by their body size (1–10 mm),²¹ aphids feeding on the same leaf are probably hardly confronted with the regional defense induced by another aphid (Fig. 1). Otherwise, they would show an increased number of test probes before first phloem activity, as described for volatile mediated plant defense in cortex cells.¹³ Circumstantial support in favor of our hypothesis is provided by production of hydrogen peroxide in the apoplast,²² which is most likely associated with the action of OGs.²² Observations of hydrogen peroxide production during aphid (Macrosiphum euphorbiae) infestation of tomato in a limited area along the leaf veins, the preferred feeding sites of this species, indicate a locally restricted defense response (Fig. 1 and ​and22).⁴ The question arises why the cell signals are not spread via plasmodesmata to adjacent cells to induce resistance in a more extended leaf area? Dissemination of the signals may be prevented by closure of plasmodesmata (Fig. 1) through callose deposition,^23,24 which is most likely directly coupled with calcium influx induced by OGs,²⁵ by apoplastic hydrogen peroxide and to a minor extent by stylet puncture (Fig. 2).^7,26Open in a separate windowFigure 1Hypothetical model on how stylet penetration induces and suppresses plant defense. Sheath saliva (light blue) that envelopes the stylet during propagation through the apoplast contains cellulase and pectinase,^17,18 enzymes producing elicitors (e.g., oligogalacturonides (oGs)) by local cell wall digestion.¹⁹ Parenchyma cells adjacent to the sheath may develop a defense response owing to signaling cascades triggered by oG-mediated Ca²⁺-influx.¹⁹ Together with a Ca²⁺-dependent transient closure of plasmodesmata by callose (black crosses),^23,24 the focused production of oGs may cause a defense response with a limited sphere of action (red—strong, brown—light, green—none). This restricted domain of defense may not be perceived by other aphids, since the settling distance is limited by the aphid body size. Nearby aphids do not show any sign of defense perception in their probing and feeding behavior.¹⁴ Signaling cascade compounds may be channeled from parenchyma cells to CCs (dashed yellow arrows), where they are subsequently released into the SEs. There they may act as long-distance systemic defense components (grey arrows). In contrast to the parenchyma domain (where only minor amounts of watery saliva are secreted), Ca²⁺-mediated reactions such as defense cascades and sieve-plate (SP) occlusion are suppressed in SEs by large amounts of watery saliva. The left aphid penetrates an SE and injects watery saliva (red cloud; ws) that inhibits local sieve-plate occlusion and,¹⁰ most likely, is transported by mass flow (black arrow) to adjacent SEs,²⁷ where occlusion is impeded as well. A short-distance systemic spread over a few centimeters may explain local suppression of plant defense resulting in a higher rate of colonization. Salivary proteins or their degradation products may serve as systemic defense signals as well (grey arrows), but may also diffuse via the PPUs into CCs where additional systemic signals are induced (yellow arrows).Open in a separate windowFigure 2Hypothetical involvement of Ca²⁺-channels in aphid-induced cell defense (detail). During probing with its stylet the aphid secretes gel saliva as a lubrication substance (light blue) into the apoplast.¹⁵ on the way to the sieve tubes, aphids briefly puncture most non-phloem cells (red) after which the puncturing sites are sealed with gel saliva.^7,16 Gel saliva also most likely prevents the influx of apoplastic calcium into pierced sieve elements (green) by sealing the penetration site.⁷ Watery saliva (red cloud), injected into the SE lumen,⁹ contains proteins which bind calcium ions (marked by X) that enter the SE via e.g., mechano sensitive Ca²⁺-channels activated by stylet penetration (blue tons).¹⁰ In this way, aphids suppress SE occlusion and activation of local defense cascades. In the parenchyma cells around the gel saliva sheath, a small cylindrical zone of defense may be induced by oligogalacturonides (oGs; brown triangles) produced by cell wall (grey) digestion.^17–19 Perceived by unknown receptor proteins (R; e.g., a receptor like protein kinase)³⁴ and kinase mediation (black dotted and dashed arrows), oGs lead to a Ca²⁺-influx through kinase activated calcium channels (orange tons).²⁵ Around the probing site, aphids apparently induce the production of superoxide by Ca²⁺-induced activation of the NADPH oxidase (violet box) and its following conversion to hydrogen peroxide (red spots) is mediated by superoxide dismutase (SoD).⁴ Hydrogen peroxide activates Ca²⁺-channels (violet tons) and diffuses through plasma membrane (curled arrows) therefore potentially acting as a intracellular signal.²⁶By contrast, Ca²⁺-influx into SEs, induced by presence of OGs or stylet insertion (Fig. 2), is not expected to trigger local defense given the abundant excretion of Ca²⁺-binding watery saliva.^7,10,25 Watery saliva may spread to down-stream and adjacent SEs through transverse and lateral sieve plates (Fig. 1).^7,27 Aphids puncturing nearby SEs may therefore encounter less severe sieve-plate occlusion which results in facilitated settling and thus in increased population growth. Aggregation of feeding aphids would self-amplify population growth until a certain density is attained. Farther from the colonization site, this effect may be lost due to dilution. Stimulation of aphid feeding by aphid infestation was observed locally on potato by Myzus persicae and M. euphorbiae, respectively, 96 h after infestation.¹³ However, a similar effect was not observed for M. persicae on Arabidopsis thaliana where aphids induced premature leaf senescence and resistance 12 h after infestation,²⁸ possibly induced by OGs.¹⁹As a speculation, OG induced Ca²⁺-influx into parenchyma cells adjacent to the salivary sheath activate Ca²⁺-induced signaling cascades via CaM,^26,29 CDPKs,^30,31 MAPKinases and reactive oxygen species (Fig. 2).³² Systemic resistance, induced by aphid infestation,^12–14 is mediated by unknown compounds such as, e.g., salivary proteins, their degradation products, signal cascade products or volatiles.¹³ Compounds produced in CCs first have to pass the PPUs, while SE signaling elements can be directly transported via mass flow (Fig. 1).The question arises if aphids profit from induced resistance on local (cortex and parenchyma cells) and systemic (distant plant organs) levels as holds for suppression of defense in SEs. Possibly settling and subsequent spread of competing pathogens/herbivores (e.g., fungi or other piercing-sucking insects) are suppressed by induced defense. In this context it is intriguing to understand how aphids cope with the self-induced systemic resistance, which probably lasts over weeks.³³     

A combinatory approach for analysis of protein sets in barley sieve-tube samples using EDTA-facilitated exudation and aphid stylectomy

This study investigated advantages and drawbacks of two sieve-tube sap sampling methods for comparison of phloem proteins in powdery mildew-infested vs. non-infested Hordeum vulgare plants. In one approach, sieve tube sap was collected by stylectomy. Aphid stylets were cut and immediately covered with silicon oil to prevent any contamination or modification of exudates. In this way, a maximum of 1muL pure phloem sap could be obtained per hour. Interestingly, after pathogen infection exudation from microcauterized stylets was reduced to less than 40% of control plants, suggesting that powdery mildew induced sieve tube-occlusion mechanisms. In contrast to the laborious stylectomy, facilitated exudation using EDTA to prevent calcium-mediated callose formation is quick and easy with a large volume yield. After two-dimensional (2D) electrophoresis, a digital overlay of the protein sets extracted from EDTA solutions and stylet exudates showed that some major spots were the same with both sampling techniques. However, EDTA exudates also contained large amounts of contaminative proteins of unknown origin. A combinatory approach may be most favourable for studies in which the protein composition of phloem sap is compared between control and pathogen-infected plants. Facilitated exudation may be applied for subtractive identification of differentially expressed proteins by 2D/mass spectrometry, which requires large amounts of protein. A reference gel loaded with pure phloem sap from stylectomy may be useful for confirmation of phloem origin of candidate spots by digital overlay. The method provides a novel opportunity to study differential expression of phloem proteins in monocotyledonous plant species.     

Nitric oxide generation in Vicia faba phloem cells reveals them to be sensitive detectors as well as possible systemic transducers of stress signals

Vascular tissue was recently shown to be capable of producing nitric oxide (NO), but the production sites and sources were not precisely determined. Here, NO synthesis was analysed in the phloem of Vicia faba in response to stress- and pathogen defence-related compounds. The chemical stimuli were added to shallow paradermal cortical cuts in the main veins of leaves attached to intact plants. NO production in the bare-lying phloem area was visualized by real-time confocal laser scanning microscopy using the NO-specific fluorochrome 4,5-diaminofluorescein diacetate (DAF-2 DA). Abundant NO generation in companion cells was induced by 500 microm salicylic acid (SA) and 10 microm hydrogen peroxide (H(2)O(2)), but the fungal elicitor chitooctaose was much less effective. Phloem NO production was found to be dependent on Ca(2+) and mitochondrial electron transport and pharmacological approaches found evidence for activity of a plant NO synthase but not a nitrate reductase. DAF fluorescence increased most strongly in companion cells and was occasionally observed in phloem parenchyma cells. Significantly, accumulation of NO in sieve elements could be demonstrated. These findings suggest that the phloem perceives and produces stress-related signals and that one mechanism of distal signalling involves the production and transport of NO in the phloem.     

Nitric oxide mediates hypoxia-induced cerebral vasodilation in humans.

Nitric oxide (NO) plays a pivotal role in the regulation of peripheral vascular tone. Its role in the regulation of cerebral vascular tone in humans remains to be elucidated. This study investigates the role of NO in hypoxia-induced cerebral vasodilatation in young healthy volunteers. The effect of the NO synthase inhibitor N(G)-monomethyl-L-arginine (L-NMMA) on the cerebral blood flow (CBF) was assessed during normoxia and during hypoxia (peripheral O(2) saturation 97 and 80%, respectively). Subjects were positioned in a magnetic resonance scanner, breathing normal air (normoxia) or a N(2)-O(2) mixture (hypoxia). The CBF was measured before and after administration of L-NMMA (3 mg/kg) by use of phase-contrast magnetic resonance imaging techniques. Administration of L-NMMA during normoxia did not affect CBF. Hypoxia increased CBF from 1,049 +/- 113 to 1,209 +/- 143 ml/min (P < 0.05). After L-NMMA administration, the augmented CBF returned to baseline (1,050 +/- 161 ml/min; P < 0.05). Similarly, cerebral vascular resistance declined during hypoxia and returned to baseline after administration of L-NMMA (P < 0.05 for both). Use of phase-contrast magnetic resonance imaging shows that hypoxia-induced cerebral vasodilatation in humans is mediated by NO.     

Ultrastructure of minor-vein phloem and assimilate export in summer and winter leaves of the symplasmically loading evergreens Ajuga reptans L., Aucuba japonica Thunb., and Hedera helix L.

Minor-vein ultrastructure and sugar export were studied in mature summer and winter leaves of the three broadleaf-evergreen species Ajuga reptans var. artropurpurescens L., Aucuba japonica Thunb. and Hedera helix L. to assess temperature effects on phloem loading. Leaves of the perennial herb Ajuga exported substantial amounts of assimilates in form of raffinose-family oligosaccharides (RFOs). Its minor-vein companion cells represent typical intermediary cells (ICs), with numerous small vacuoles and abundant plasmodesmal connectivity to the bundle sheath. The woody plants Hedera and Aucuba translocated sucrose as the dominant sugar species, and only traces of RFOs. Their minor-vein phloem possessed a layer of highly vacuolated cells (VCs) intervening between mesophyll and sieve elements. Depending on their location and ontogeny, VCs were classified either as companion or parenchyma cells. Both cell types showed symplasmic continuity to the adjacent mesophyll tissue although at a lower plasmodesmal frequency compared to the Ajuga ICs. p-Chloromercuribenzenesulfonic acid did not reduce leaf sugar export in any of the plants, indicating a symplasmic mode of phloem loading. Winter leaves did not show symptoms of frost injury, and the vacuolar pattern in ICs and VCs was equally prominent in both seasons. Starch accumulation as a result of reduced phloem loading was not observed to be triggered by low temperature. In contrast, high amounts of starch were found in mesophyll and bundle-sheath cells of summer leaves. Physiological data on season-dependent leaf exudation showed the maintenance of sugar export in cold-acclimated winter leaves.     

DRESS: a database of REfined solution NMR structures

Several studies have shown that biomolecular NMR structures are often of lower quality when compared to crystal structures, and consequently they are often excluded from structural analyses. We present a publicly available database of re-refined NMR structures, exhibiting significantly improved quality. This database (available at http://www.cmbi.kun.nl/dress/) presents a uniformly refined and validated set of structural models that improves the value of these NMR structures as input for experimental and theoretical studies in many fields of research.