Hubert H. Felle

Plant recognition of symbiotic bacteria requires two LysM receptor-like kinases

Although most higher plants establish a symbiosis with arbuscular mycorrhizal fungi, symbiotic nitrogen fixation with rhizobia is a salient feature of legumes. Despite this host range difference, mycorrhizal and rhizobial invasion shares a common plant-specified genetic programme controlling the early host interaction. One feature distinguishing legumes is their ability to perceive rhizobial-specific signal molecules. We describe here two LysM-type serine/threonine receptor kinase genes, NFR1 and NFR5, enabling the model legume Lotus japonicus to recognize its bacterial microsymbiont Mesorhizobium loti. The extracellular domains of the two transmembrane kinases resemble LysM domains of peptidoglycan- and chitin-binding proteins, suggesting that they may be involved directly in perception of the rhizobial lipochitin-oligosaccharide signal. We show that NFR1 and NFR5 are required for the earliest physiological and cellular responses to this lipochitin-oligosaccharide signal, and demonstrate their role in the mechanism establishing susceptibility of the legume root for bacterial infection.

Auxin causes oscillations of cytosolic free calcium and pH inZea mays coleoptiles

In epidermal cells of maize (Zea mays L.) coleoptiles, cytosolic pH (pHc), cytosolic free calcium, membrane potential and changes thereof were monitored continuously and simultaneously (pHc/,ψm, Ca2+/ψm) using double-barrelled ion-sensitive microelectrodes. In the resting cells the cytosolic pH was 7.3–7.5 and the concentration of free calcium was 119±24 nM. One-micromolar indole-3-acetic acid (IAA), added to the external medium at pH 6.0 triggered oscillations inψm, pHc and free calcium with a period of 20 to 30 min. Acidification of the cytosolic pH increased the cytosolic free calcium. Theψm oscillations are attributed to changes in activity of the H+-extrusion pump at the plasmalemma, triggered off by ΔpH and controlled by pH regulation (pH oscillation). The origin of the pHc and Ca2+ changes remains unclear, but is possibly caused by auxin-receptor-induced lipid breakdown and subsequent second-messenger formation. It is suggested that the observed cytosolic pH and Ca2+ changes are intrinsically interrelated, and it is concluded that this onset of regulatory processes through the phytohormone IAA is indicative of calcium and protons mediating early auxin action in maize coleoptiles. It is further concluded that the double-barrelled ion-sensitive microelectrode is an invaluable tool for investigating in-vivo hormone action in plant tissues.

KAT1 is not essential for stomatal opening

It is generally accepted that K+ uptake into guard cells via inward-rectifying K+ channels is required for stomatal opening. To test whether the guard cell K+ channel KAT1 is essential for stomatal opening, a knockout mutant, KAT1∷En-1, was isolated from an En-1 mutagenized Arabidopsis thaliana population. Stomatal action and K+ uptake, however, were not impaired in KAT1-deficient plants. Reverse transcription–PCR experiments with isolated guard cell protoplasts showed that in addition to KAT1, the K+ channels AKT1, AKT2/3, AtKC1, and KAT2 were expressed in this cell type. In impalement measurements, intact guard cells exhibited inward-rectifying K+ currents across the plasma membrane of both wild-type and KAT1∷En-1 plants. This study demonstrates that multiple K+ channel transcripts exist in guard cells and that KAT1 is not essential for stomatal action.

Cytoplasmic free calcium in Riccia fluitans L. and Zea mays L.: Interaction of Ca2+ and pH?

In cells of Zea mays (root hairs, coleoptiles) and Riccia fluitans (rhizoids, thalli) intracellular Ca2+ and pH have been measured with double-barrelled microelectrodes. Free Ca2+ activities of 109–187 nM (Riccia rhizoids), 94–160 nM (Riccia thalli), 145–231 nM (Zea root hairs), 84–143 nM (Zea coleoptiles) were found, and therefore identified as cytoplasmic. In a few cases (Riccia rhizoids), free Ca2+ was in the lower millimolar range (2.3±0.8 mM). A change in external Ca2+ from 0.1 to 10 mM caused an initial and short transient increase in cytoplasmic free Ca2+ which finally levelled off at about 0.2 pCa unit below the control, whereas in the presence of cyanide the Ca2+ activity returned to the control level. It is suggested that this behaviour is indicative of active cellular Ca2+ regulation, and since it is energy-dependent, may involve a Ca2+-ATPase. Acidification of the cytoplasmic pH and alkalinization of the vacuolar pH lead to a simultaneous increase in cytoplasmic free Ca2+, while alkalinization of pHc decreased the Ca2+ activity. Since this is true for such remote organisms as Riccia and Zea, it may be concluded that regulation of cytoplasmic pH and free Ca2+ are interrelated. It is further concluded that double-barrelled microelectrodes are useful tools for investigations of intracellular ion activities in plant cells.

K+ channel profile and electrical properties of Arabidopsis root hairs

Ion channels and solute transporters in the plasma membrane of root hairs are proposed to control nutrient uptake, osmoregulation and polar growth. Here we analyzed the molecular components of potassium transport in Arabidopsis root hairs by combining K+‐selective electrodes, reverse transcription‐PCR, and patch‐clamp measurements. The two inward rectifiers AKT1 and ATKC1 as well as the outward rectifier GORK dominated the root hair K+ channel pool. Root hairs of AKT1 and ATKC1 loss‐of‐function plants completely lack the K+ uptake channel or exhibited altered properties, respectively. Upon oligochitin‐elicitor treatment of root hairs, transient changes in K+ fluxes and membrane polarization were recorded in wild‐type plants, while akt1‐1 root hairs showed a reduced amplitude and pronounced delay in the potassium re‐uptake process. This indicates that AKT1 and ATKC1 represent essential α‐subunits of the inward rectifier. Green fluorescent protein (GFP) fluorescence following ballistic bombardment with GORK promoter‐GFP constructs as well as analysis of promoter‐GUS lines identified this K+ outward rectifier as a novel ion channel expressed in root hairs. Based on the expression profile and the electrical properties of the root hair plasma membrane we conclude that AKT1‐, ATKC‐ and GORK‐mediated potassium transport is essential for osmoregulation and repolarization of the membrane potential in response to elicitors.

Alamethicin-induced electrical long distance signaling in plants

Systemic signaling was investigated in both a dicot (Vicia faba) and a monocot (Hordeum vulgare) plant. Stimuli were applied to one leaf (S-leaf), and apoplastic responses were monitored on a distant leaf (target; T-leaf) with microelectrodes positioned in substomatal cavities of open stomata. Leaves that had been injured by cutting and to which a variety of cations were subsequently added caused voltage transients at the T-leaf, which are neither action potentials nor variation potentials: with respect to the cell interior, the initial polarity of these voltage transients is hyperpolarizing; they do not obey the all-or-none rule but depend on both the concentration and the type of substance added and propagate at 5 to 10 cm min−1. This response is thought to be due to the stimulation of the plasma membrane H+-ATPase, a notion supported by the action of fusicoccin, which also causes such voltage transients to appear on the T-leaf, whereas orthovanadate prevents their propagation. Moreover, apoplastic ion flux analysis reveals that, in contrast to action or variation potentials, all of the investigated ion movements (Ca2+, K+, H+, and Cl−) occur after the voltage change begins. We suggest that these wound-induced “system potentials” represent a new type of electrical long-distance signaling in higher plants.

The Cytosolic Ca2+ Concentration Gradient of Sinapis alba Root Hairs as Revealed by Ca2+-Selective Microelectrode Tests and Fura-Dextran Ratio Imaging

Using Ca2+-selective microelectrodes and fura 2-dextran ratio imaging, the cytosolic free [Ca2+] was measured in Sinapis alba root hair cells. Both methods yielded comparable results, i.e. values between 158 to 251 nM for the basal [Ca2+] of the cells and an elevated [Ca2+] of 446 to 707 nM in the tip region. The zone of elevated [Ca2+] reaches 40 to 60 [mu]m into the cell and is congruent with the region of inwardly directed Ca2+ net currents measured with an external Ca2+- selective vibrating electrode. The channel-blocker La3+ eliminates these currents, stops growth, and almost completely eliminates the cytosolic [Ca2+] gradient without affecting the basal level of the ion. Growth is also inhibited by pressure-injected dibromo-1,2-bis(o-aminophenoxy)ethane-N,N,N[prime],N[prime]-tetraacetic acid, which causes a decrease in the [Ca2+] in the tip in a concentration-dependent manner. Indole-3-acetic acid, used as a model stimulus, decreases cytosolic free [Ca2+] by 0.2 to 0.3 pCa units in the tip, but only by about 0.1 pCa unit in the shank. Nongrowing root hairs may or may not display a [Ca2+] gradient, but still reversibly respond to external stimuli such as La3+, Ca2+, or indole-3-acetic acid with changes in cytosolic free [Ca2+]. During short time periods, dicyclohexylcarbodiimide inhibition of the plasma membrane H+-ATPase, which stops growth, does not abolish the [Ca2+] gradient, nor does it change significantly the basal [Ca2+] level. We conclude that the cytosolic [Ca2+] gradient and an elevated [Ca2+] in the tip, as in other tip-growing cells, is essential for tip growth in root hairs; however, its presence does not indicate growth under all circumstances. We argue that with respect to Ca2+, tip growth regulation and responses to external signals may not interfere with each other. Finally, we suggest that the combination of the methods applied adds considerably to our understanding of the role of cytosolic free [Ca2+] in signal transduction and cellular growth.

Regulation of Intracellular pH in Plant Cells

Publisher Summary This chapter reviews the basic principles of the techniques used for intracellular pH measurement in the main cell compartments—namely, cytoplasm and vacuole. Alongwith being both substrate and product in numerous metabolic reactions, protons fulfill the regulatory role of coordinating the activities of enzyme-catalyzed pathways, membrane transport, and other regulators. The protons connect cellular compartments and also play important roles in intercellular traffic. The sudden pH shifts may impose critical loads on the cells. The technical improvements that have been brought about since the previously published reviews are described in the chapter. The technique involves the extraction of cell sap and the measurement of its pH with a glass electrode. It is used for various types of plant materials. The principle of this technique is based on three requirements: the probe molecule is metabolically inert, only the uncharged form is membrane permeant, and the probe is not to change the pH of the respective compartment. The distribution of protons within a plant cell appears as a critical element of cell organization and function.

The electrical response of maize to auxins.

The electrical response of Zea mays coleoptiles and suspension cultured cells to several growth-promoting auxins (IAA, IBA, 2,4-D, 2,4,5-T, 1-NAA) and some of their structural analogues (2,3-D, 2-NAA) has been tested. In coleoptile two typical electrical responses to IAA are observed: an immediated rapid depolarization, and a hyperpolarization following 7-10 minutes after the first external addition of IAA. Of the other tested compounds only 1-NAA significantly depolarized the cells, whereas all auxins as well as the analogues evoked delayed hyperpolarizations. In contrast, the suspension cells were not hyperpolarized by any of the tested compounds, but were strongly depolarized by IAA, 1-NAA, and to a lesser extent by 2-NAA. In these cells IAA and 1-NAA induced inwardly directed currents of positive charge which both saturated around 12 mA/m2. The strong pH-dependence together with the half-maximal currents 0.49 microM IAA and 0.76 microM 1-NAA point to a symport of the anions with at least 2H+. The delayed plasma membrane hyperpolarization is a different response, and seems to be initiated by the protonated auxin species. In accordance with the current literature, it is interpreted as consequence of a stimulated proton extrusion. The finding that all tested compounds evoked a hyperpolarization, makes this response unspecific. It is concluded that a stimulation of proton extrusion is a necessary, but not sufficient step to induce elongation growth.

Sieve Element Ca2+ Channels as Relay Stations between Remote Stimuli and Sieve Tube Occlusion in Vicia faba

Damage induces remote occlusion of sieve tubes in Vicia faba by forisome dispersion, triggered during the passage of an electropotential wave (EPW). This study addresses the role of Ca2+ channels and cytosolic Ca2+ elevation as a link between EPWs and forisome dispersion. Ca2+ channel antagonists affect the initial phase of the EPW as well as the prolonged plateau phase. Resting levels of sieve tube Ca2+ of ∼50 nM were independently estimated using Ca2+-selective electrodes and a Ca2+-sensitive dye. Transient changes in cytosolic Ca2+ were observed in phloem tissue in response to remote stimuli and showed profiles similar to those of EPWs. The measured elevation of Ca2+ in sieve tubes was below the threshold necessary for forisome dispersion. Therefore, forisomes need to be associated with Ca2+ release sites. We found an association between forisomes and endoplasmic reticulum (ER) at sieve plates and pore-plasmodesma units where high-affinity binding of a fluorescent Ca2+ channel blocker mapped an increased density of Ca2+ channels. In conclusion, propagation of EPWs in response to remote stimuli is linked to forisome dispersion through transiently high levels of parietal Ca2+, release of which depends on both plasma membrane and ER Ca2+ channels.