Leaf thionins, a novel class of putative defence factors

Leaf thionins of barley have been identified as a novel class of highly abundant polypeptides with antifungal activity, which are present in walls and vacuoles of barley leaf cells. Similar thionins occur not only in monocotyledonous but also in various dicotyledonous plants. The leaf thionins of barley are encoded by a complex multigene family, which consists of at least 50–100 members per haploid genome. The toxicity of these thionins for plant pathogenic fungi and the fact that their synthesis can also be triggered by pathogens strongly suggest that leaf thionins are involved in the mechanism of plant defence against microbiol infection.     

植物细胞质膜离子通道研究进展

多种有机和无机离子作为重要的营养物质、渗透物质、辅酶和信号分子, 参与植物生殖、生长发育和逆境反应等多种生物学过程。离子通道是离子跨质膜和内膜运动的重要渠道和动态调控因子, 直接影响和调控细胞内离子浓度及亚细胞分布的动态变化。目前, 植物尤其是模式植物拟南芥(Arabidopsis thaliana)的多个离子通道家族被先后鉴定出来, 其中部分离子通道蛋白定位在细胞质膜上, 其基本生物学功能, 诸如蛋白结构、离子选择性和通透性、门控特点、活性调控机理以及不同离子通道之间的协同关系等均取得重要进展。该文概要介绍近年来植物细胞质膜离子通道方面的研究进展。     

A laser microsurgical method of cell wall removal allows detection of largeconductance ion channels in the guard cell plasma membrane

Application of patch clamp techniques to higher-plant cells has been subject to the limitation that the requisite contact of the patch electrode with the cell membrane necessitates prior enzymatic removal of the plant cell wall. Because the wall is an integral component of plant cells, and because cell-wall-degrading enzymes can disrupt membrane properties, such enzymatic treatments may alter ion channel behavior. We compared ion channel activity in enzymatically isolated protoplasts of Vicia faba guard cells with that found in membranes exposed by a laser microsurgical technique in which only a tiny portion of the cell wall is removed while the rest of the cell remains intact within its tissue environment. "Laser-assisted" patch clamping reveals a new category of high-conductance (130 to 361 pS) ion channels not previously reported in patch clamp studies on plant plasma membranes. These data indicate that ion channels are present in plant membranes that are not detected by conventional patch clamp techniques involving the production of individual plant protoplasts isolated from their tissue environment by enzymatic digestion of the cell wall. Given the large conductances of the channels revealed by laser-assisted patch clamping, we hypothesize that these channels play a significant role in the regulation of ion content and electrical signalling in guard cells.     

A laser microsurgical method of cell wall removal allows detection of largeconductance ion channels in the guard cell plasma membrane

Summary Application of patch clamp techniques to higher-plant cells has been subject to the limitation that the requisite contact of the patch electrode with the cell membrane necessitates prior enzymatic removal of the plant cell wall. Because the wall is an integral component of plant cells, and because cell-wall-degrading enzymes can disrupt membrane properties, such enzymatic treatments may alter ion channel behavior. We compared ion channel activity in enzymatically isolated protoplasts ofVicia faba guard cells with that found in membranes exposed by a laser microsurgical technique in which only a tiny portion of the cell wall is removed while the rest of the cell remains intact within its tissue environment. “Laserassisted” patch clamping reveals a new category of high-conductance (130 to 361 pS) ion channels not previously reported in patch clamp studies on plant plasma membranes. These data indicate that ion channels are present in plant membranes that are not detected by conventional patch clamp techniques involving the production of individual plant protoplasts isolated from their tissue environment by enzymatic digestion of the cell wall. Given the large conductances of the channels revealed by laser-assisted patch clamping, we hypothesize that these channels play a significant role in the regulation of ion content and electrical signalling in guard cells.     

Proton magnetic resonance studies of barley and wheat thionins: structural homology with crambin

The thionins comprise a group of very basic proteins of Mr approximately 5000 found in the seeds of Gramineae. They each contain 45 amino acid residues arranged along a single polypeptide chain that is constrained by four disulfide bridges. Five thionins of known sequence, from barley and wheat, have been investigated and compared by 1H NMR spectroscopy at 600 MHz. From their spectral characteristics it is concluded that the five proteins have very similar, nonrandom conformations in 2H2O solution. Moreover, on the basis of selective nuclear Overhauser experiments at 300 MHz, features of their secondary and tertiary structures are shown to be similar to those of crambin, a related, hydrophobic protein extracted from seeds of the crucifer Crambe abyssinica. The strong compositional homology of the thionins facilitates the assignment of methyl and aromatic resonances, as only a few residues are replaced and these are at known sites. The substitution of leucine for an isoleucine does not affect significantly the local magnetic environment, suggesting that those isomeric side chains easily accommodate the same spatial constraints. A fast hydrogen-deuterium exchange is observed at pH 6.25, 25 degrees C. This indicates that, although of folded conformation, the thionins are structurally flexible polypeptides that efficiently expose all amides to the solvent.     

THE ULTRASTRUCTURE OF COTYLEDONARY TISSUE FROM GOSSYPIUM HIRSUTUM L. SEEDS

Quiescent cottonseeds stored in a dry, anaerobic situation for over a year have been shown to contain cells whose contents are ultrastructurally similar to those of normal, fully hydrated plant cells. Plastids, mitochondria, and nuclei of the cells of cotyledon tissue in dry seeds possess normal-looking double membranes even under conditions of extreme desiccation. Previous reports have indicated on the basis of light microscopic work, that the cells of certain dry seeds do not possess nuclear membranes or mitochondria. The cells of the dry cottonseed do contain these structures, however. Dictyosomes have not been observed in the spongy parenchymal cells of the cotyledon tissue; it is suggested that they are concerned with translocation and/or utilization of material. The storage materials in the cells, protein and oil, are contained in vacuolar areas enclosed by a single membrane.     

Intracellular thionins of barley. A second group of leaf thionins closely related to but distinct from cell wall-bound thionins

Leaf thionins of barley have been identified as a novel class of cell wall proteins, toxic to plant pathogenic fungi, and possibly involved in the defense mechanism of plants (Bohlmann, H., Clausen, S., Behnke, S., Giese, H., Hiller, C., Reimann-Philipp, U., Schrader, G., Barkholt, V., and Apel, K., (1988) EMBO J. 7, 1559-1565). In the present work a second subfraction of thionins has been detected within the leaf cell, mainly in the vacuole. Thionins of both groups are closely related to each other. They are toxic to phytopathogenic fungi as well as to plant protoplasts, they share similar amino acid sequences, and their synthesis in etiolated seedlings of barley is down-regulated by light. Despite these similarities each of the two subfractions of thionins could be clearly distinguished by its subcellular distribution. In ultrathin sections of embedded etiolated leaf material, cell wall thionins could be immunogold labeled specifically by an antiserum raised against a fusion protein of Escherichia coli beta-galactosidase and the 15,000 Mr precursor polypeptide of thionins. This antiserum did not react with intracellular thionins. Inversely, intracellular thionins were recognized specifically by an anti-serum raised against soluble leaf thionins. The possible function of intracellular thionins as part of a defense mechanism has been discussed.     

Ionic channels,ion transport and plant cell membranes: Potential applications of the patch-clamp technique

Conclusion Exciting innovations in the methodologies available for the study of ionic channels (notably in animal cells) have allowed hitherto impossible advances in the comprehension of both structure and function. In using channels like the Na channel and the AChR as examples of these strategies, we have tried to give a concise but up to date account of the current possibilities (in particular, the patch-clamp) for research in membrane physiology. That few of these techniques have been applied to plant cell membranes simply indicates the scope for advancement in the understanding of some problems fundamental to plant physiology. The mechanisms of transport involved in processes known to be important for the life of plant cells (e.g., regulation of cytoplasmic and vacuolar potential differences and pH, maintenance of vacuolar turgor pressure, accumulation of metabolites and their counterions, response to environmental stimuli) are relatively speaking, poorly characterized. In that ion fluxes through plasmalemma and tonoplast membranes are at least in part likely to be via ionic channels for all of these processes, an important step forward would be the application of patch-clamp techniques for the direct demonstration of a channel mechanism and the subsequent elucidation of their role.     

Using planar lipid-bilayers to study plant ion channels

Ion channels are found in most plant membranes. They catalyse the rapid passive uniport of particular ions with varying selectivity. Planar lipid-bilayer (PLB) techniques have been developed to study the electrical activities of single ion channels in well-defined lipid and aqueous environments. They greatly facilitate both the biophysical and biochemical characterisation of ion channels and complement both conventional impaling electrode and membrane-patch voltage-clamping (patch-clamping) electrophysiological techniques applied in vivo. Bilayers can be formed across the end of patch-clamp pipettes or across apertures in specifically designed chambers. Ion channels in native membranes and purified, genetically altered or synthetic ion channels, proteins and peptides can all be studied in PLBs. The main applications of PLBs are (1) to study ion channels in membranes inaccessible to patch-clamp electrodes, (2) to provide a functional assay system during channel-protein purification and (3) to investigate the relationship between the molecular structure of ion channels and their conductance properties. In the present article we describe the techniques available for reconstitution and analysis of ion channels in PLBs and discuss how the PLB technique has been, and may be, useful to the study of plant ion channels.     

The Role of Thionins in Plant Protection

Thionins are a group of small (5000 Da), sulfur-rich plant proteins found mainly in cereals and mistletoes. Their three-dimensional structures are very compact and amphipathic, stabilized by three or four disulfide bridges. Thionins are usually basic and exert toxicity in various biological systems by destroying membranes. Thionins are synthesized as preproproteins and secreted into vacuoles, protein bodies, and the cell wall. Their antibacterial and antifungal activities point to a role as plant defense proteins. Support for this possible function comes particularly from work on the leaf thionins of barley, showing that these proteins can be induced by several stress factors. Infection of barley with mildew, one of its most devastating pathogens, leads to an incorporation of leaf thionins into papillae in incompatible interactions. The possible role of thionins to enhance the resistance of crop plants by genetic engineering is discussed.     

Isolation and characterization of cDNAs encoding viscotoxins of mistletoe (Viscum album).

Viscotoxins have been isolated from leaf homogenates of European mistletoe (Viscum album L.) and purified to apparent homogeneity. Antisera raised against these polypeptides were used to screen a cDNA expression library in lambda gt11. Two positive clones have been isolated, one encoding a full-length preprotein of viscotoxin A3 and the other encoding the precursor of viscotoxin B. Besides the viscotoxin domain the precursor contained a signal sequence and an acidic polypeptide domain. Similar higher molecular mass precursor proteins have been described for thionins of leaves and seeds of barley. Even though the acidic part of the viscotoxin precursor is much shorter than the corresponding domain of the precursors of the leaf and seed thionins of barley, both the negative charge and the number and the relative position of cysteine residues have been conserved within the acidic domain. This result is consistent with our proposal that the acidic domain of the thionin precursor may play an important role in keeping the thionin inactive within the plant cell.     

Isolation and characterization of cDNAs coding for leaf-specific thionins closely related to the endosperm-specific hordothionin of barley (Hordeum vulgare L.)

Summary In etiolated barley seedlings a highly abundant mRNA encoding a 15 000 M_r polypeptide is present whose concentration rapidly declines upon illumination. The amino acid sequence of the 15 000 M_r polypeptide has been deduced from cDNA sequences and the polypeptide has been identified as a high-molecular-weight thionin precursor. Closely related thionins, most of them highly toxic, have been described previously in several higher plants. In cereals the occurrence of these thionins has been thought to be confined to the seeds. Our present data demonstrate that, in additon to endosperm-specific hordothionin mRNA, a closely related but distinct second group of thionin mRNAs is present in the barley leaf during early seedling development. Since the appearance of the bordothionin mRNA is not controlled by light, two different gene families for thionins exist whose expression seems to be under a different mode of developmental control.Dedicated to Prof. W. Halbsguth on the occasion of his 75th birthday     

Leaf-specific thionins of barley-a novel class of cell wall proteins toxic to plant-pathogenic fungi and possibly involved in the defence mechanism of plants

A novel class of highly abundant polypeptides with antifungal activity has been detected in cell walls of barley leaves. Similar polypeptides known as thionins occur not only in monocotyledonous but also in various dictoyledonous plants. The leaf-specific thionins of barley are encoded by a complex multigene family, which consists of at least 50-100 members per haploid genome. All of these genes are confined to chromosome 6. The toxicity of these thionins for plant pathogenic fungi and the fact that their synthesis can also be triggered by pathogens strongly suggest that thionins are a naturally occurring, inducible plant protein possibly involved in the mechanism of plant defence against microbial infections.     

Glutamate receptors in plants

Ionotropic glutamate receptors function in animals as glutamate-gated non-selective cation channels. Numerous glutamate receptor-like (GLR) genes have been identified in plant genomes, and plant GLRs are predicted, on the basis of sequence homology, to retain ligand-binding and ion channel activity. Non-selective cation channels are ubiquitous in plant membranes and may function in nutrient uptake, signalling and intra-plant transport. However, there is little evidence for amino acid gating of plant ion channels. Recent evidence suggests that plant GLRs do encode non-selective cation channels, but that these channels are not gated by amino acids. The functional properties of these proteins and their roles in plant physiology remain a mystery. The problems surrounding characterization and assignation of function to plant GLRs are discussed in this Botanical Briefing, and potential roles for GLR proteins as non-selective cation channels involved in metabolic signalling are described.     

Lipid-transfer proteins: Tools for manipulating membrane lipids

Like other eukaryotic cells, plant cells contain proteins able to bind or to transfer lipids. Since they are able to facilitate movements of various phospholipids between membranes and are also capable of binding fatty acids or acyl-CoAs, they have been termed lipid-transfer proteins (LTP). LTPs are basic proteins containing 90 to 95 residues (molecular mass 9 kDa), eight of them being cysteines found in conserved locations. These proteins have been used to manipulate in vitro the lipid composition of isolated membranes either from plant or mammalian sources. In addition to purified LTPs, recombinant LTPs produced by genes expressed in microorganisms can be used for this purpose. Several genes coding for these proteins have been characterized in various plants with different patterns of expression. However, it remains to be investigated whether these recombinant proteins behave functionally as LTPs. The use of purified or recombinant LTPs is promising for the study of the effect of lipid composition on membrane functional properties.     

A distributed parameter identification problem in neuronal cable theory models

Dendritic and axonal processes of nerve cells, along with the soma itself, have membranes with spatially distributed densities of ionic channels of various kinds. These ionic channels play a major role in characterizing the types of excitable responses expected of the cell type. These densities are usually represented as constant parameters in neural models because of the difficulty in experimentally estimating them. However, through microelectrode measurements and selective ion staining techniques, it is known that ion channels are non-uniformly spatially distributed. This paper presents a non-optimization approach to recovering a single spatially non-uniform ion density through use of temporal data that can be gotten from recording microelectrode measurements at the ends of a neural fiber segment of interest. The numerical approach is first applied to a linear cable model and a transformed version of the linear model that has closed-form solutions. Then the numerical method is shown to be applicable to non-linear nerve models by showing it can recover the potassium conductance in the Morris-Lecar model for barnacle muscle, and recover the spine density in a continuous dendritic spine model by Baer and Rinzel.     

Synergistic Enhancement of the Antifungal Activity of Wheat and Barley Thionins by Radish and Oilseed Rape 2S Albumins and by Barley Trypsin Inhibitors

Although thionins and 2S albumins are generally considered as storage proteins, both classes of seed proteins are known to inhibit the growth of pathogenic fungi. We have now found that the wheat (Triticum aestivum L.) or barley (Hordeum vulgare L.) thionin concentration required for 50% inhibition of fungal growth is lowered 2- to 73-fold when combined with 2S albumins (at sub- or noninhibitory concentrations) from radish (Raphanus sativus L.) or oilseed rape (Brassica napus L.). Furthermore, the thionin antifungal activity is synergistically enhanced (2- to 33-fold) by either the small subunit or the large subunit of the radish 2S albumins. Three other 2S albumin-like proteins, the barley trypsin inhibitor and two barley Bowman-Birk-type trypsin inhibitor isoforms, also act synergistically with the thionins (2- to 55-fold). The synergistic activity of thionins combined with 2S albumins is restricted to filamentous fungi and to some Gram-positive bacteria, whereas Gram-negative bacteria, yeast, cultured human cells, and erythrocytes do not show an increased sensitivity to thionin/albumin combinations (relative to the sensitivity to the thionins alone). Scanning electron microscopy and measurement of K+ leakage from fungal hyphae revealed that 2S albumins have the same mode of action as thionins, namely the permeabilization of the hyphal plasmalemma. Moreover, 2S albumins and thionins act synergistically in their ability to permeabilize fungal membranes.     

Two MscS homologs provide mechanosensitive channel activities in the Arabidopsis root

In bacterial and animal systems, mechanosensitive (MS) ion channels are thought to mediate the perception of pressure, touch, and sound [1-3]. Although plants respond to a wide variety of mechanical stimuli, and although many mechanosensitive channel activities have been characterized in plant membranes by the patch-clamp method, the molecular nature of mechanoperception in plant systems has remained elusive [4]. Likely candidates are relatives of MscS (Mechanosensitive channel of small conductance), a well-characterized MS channel that serves to protect E. coli from osmotic shock [5]. Ten MscS-Like (MSL) proteins are found in the genome of the model flowering plant Arabidopsis thaliana[4, 6, 7]. MSL2 and MSL3, along with MSC1, a MscS family member from green algae, are implicated in the control of organelle morphology [8, 9]. Here, we characterize MSL9 and MSL10, two MSL proteins found in the plasma membrane of root cells. We use a combined genetic and electrophysiological approach to show that MSL9 and MSL10, along with three other members of the MSL family, are required for MS channel activities detected in protoplasts derived from root cells. This is the first molecular identification and characterization of MS channels in plant membranes.     

Organ-specific expression of highly divergent thionin variants that are distinct from the seed-specific crambin in the crucifer Crambe abyssinica

Most thionins of higher plants are toxic to various bacteria, fungi, and animal and plant cells. The only known exception is the seed-specific thionin, crambin, of the crucifer Crambe abyssinica. Crambin has no net charge, is very hydrophobic and exhibits no toxicity. In the present work, the organization of the crambin precursor polypeptide was deduced from cDNA sequences. The precursor shows a domain structure similar to that of the preproprotein of other thionins, which contains a signal peptide, a thionin domain and a C-terminal amino acid extension. Unlike the thionin precursors studied thus far, both the thionin domain and the C-terminal amino acid extension of the crambin precursor have no net charge and are hydrophobic, thus facilitating their interaction, by analogy to that proposed for the corresponding domains of other thionin precursors that have positive and negative charges. The existence of a large number of novel and highly variable thionin variants in Crambe abyssinica has been deduced from cDNA sequences that were amplified by the polymerase chain reaction (PCR) from RNA of seeds, leaves and cotyledons. While the deduced amino acid sequences of the thionin domains of most of these thionin precursor molecules are highly divergent, the two other domains are conserved. Most of the predicted thionin variants are positively charged. The presence of positively charged residues in the thionin domains consistently correlates with the presence of a negatively charged residue in the C-terminal amino acid extension of the various thionin precursors. The different thionin variants are encoded by distinct sets of genes and are expressed in an organ-specific manner.     

Organ-specific expression of highly divergent thionin variants that are distinct from the seed-specific crambin in the crucifer Crambe abyssinica

Most thionins of higher plants are toxic to various bacteria, fungi, and animal and plant cells. The only known exception is the seed-specific thionin, crambin, of the crucifer Crambe abyssinica. Crambin has no net charge, is very hydrophobic and exhibits no toxicity. In the present work, the organization of the crambin precursor polypeptide was deduced from cDNA sequences. The precursor shows a domain structure similar to that of the preproprotein of other thionins, which contains a signal peptide, a thionin domain and a C-terminal amino acid extension. Unlike the thionin precursors studied thus far, both the thionin domain and the C-terminal amino acid extension of the crambin precursor have no net charge and are hydrophobic, thus facilitating their interaction, by analogy to that proposed for the corresponding domains of other thionin precursors that have positive and negative charges. The existence of a large number of novel and highly variable thionin variants in Crambe abyssinica has been deduced from cDNA sequences that were amplified by the polymerase chain reaction (PCR) from RNA of seeds, leaves and cotyledons. While the deduced amino acid sequences of the thionin domains of most of these thionin precursor molecules are highly divergent, the two other domains are conserved. Most of the predicted thionin variants are positively charged. The presence of positively charged residues in the thionin domains consistently correlates with the presence of a negatively charged residue in the C-terminal amino acid extension of the various thionin precursors. The different thionin variants are encoded by distinct sets of genes and are expressed in an organ-specific manner.