Identification of a cowpea gamma-thionin with bactericidal activity

Antimicrobial peptides are an abundant group of proteinaceous compounds widely produced in the plant kingdom. Among them, the gamma-thionin family, also known as plant defensins, represents one typical family and comprises low molecular mass cysteine-rich proteins, usually cationic and distributed in different plant tissues. Here, we report the purification and characterization of a novel gamma-thionin from cowpea seeds (Vigna unguiculata), named Cp-thionin II, with bactericidal activity against Gram-positive and Gram-negative bacteria. Once the primary structure was elucidated, molecular modelling experiments were used to investigate the multimerization and mechanism of action of plant gamma-thionins. Furthermore, Cp-thionin II was also localized in different tissues in cowpea seedlings during germination in contrasting conditions, to better understand the plant protection processes. The use of plant defensins in the construction of transgenic plants and also in the production of novel drugs with activity against human pathogens is discussed.     

Plant defensins

Plant defensins are small, basic peptides that have a characteristic three-dimensional folding pattern that is stabilized by eight disulfide-linked cysteines. They are termed plant defensins because they are structurally related to defensins found in other types of organism, including humans. To date, sequences of more than 80 different plant defensin genes from different plant species are available. In Arabidopsis thaliana, at least 13 putative plant defensin genes (PDF) are present, encoding 11 different plant defensins. Two additional genes appear to encode plant defensin fusions. Plant defensins inhibit the growth of a broad range of fungi but seem nontoxic to either mammalian or plant cells. Antifungal activity of defensins appears to require specific binding to membrane targets. This review focuses on the classification of plant defensins in general and in Arabidopsis specifically, and on the mode of action of plant defensins against fungal pathogens.     

Antimicrobial Peptides from Plants

Peptides with antimicrobial properties are present in most if not all plant species. All plant antimicrobial peptides isolated so far contain even numbers of cysteines (4, 6, or 8), which are all pairwise connected by disulfide bridges, thus providing high stability to the peptides. Based on homologies at the primary structure level, plant antimicrobial peptides can be classified into distinct families including thionins, plant defensins, lipid transfer proteins, and he vein- and knottin-type antimicrobial peptides. Detailed three-dimensional structure information has been obtained for one or more members of these peptide families. All antimicrobial peptides studied thus far appear to exert their antimicrobial effect at the level of the plasma membrane of the target microorganism, but the different peptide types are likely to act via different mechanisms. Antimicrobial peptides can occur in all plant organs. In unstressed organs, antimicrobial peptides are usually most abundant in the outer cell layer lining the organ, which is consistent with a role for the antimicrobial peptides in constitutive host defense against microbial invaders attacking from the outside. Thionins are predominantly located intracellularly but are also found in the extracellular space, whereas most plant defensins and lipid transfer proteins are deposited exclusively in the extracellular space. In a number of plant species, a strong induction of genes expressing either thionins, plant defensins, or lipid transfer proteins has been observed on infection of the leaves by microbial pathogens. Hence, antimicrobial peptides can also take part in the inducible defense response of plants. Constitutive expression in transgenic plants of heterologous antimicrobial peptide genes has been achieved, which in some cases has led to enhanced resistance to particular microbial plant pathogens.     

Petunia floral defensins with unique prodomains as novel candidates for development of fusarium wilt resistance in transgenic banana plants

Antimicrobial peptides are a potent group of defense active molecules that have been utilized in developing resistance against a multitude of plant pathogens. Floral defensins constitute a group of cysteine-rich peptides showing potent growth inhibition of pathogenic filamentous fungi especially Fusarium oxysporum in vitro. Full length genes coding for two Petunia floral defensins, PhDef1 and PhDef2 having unique C-terminal 31 and 27 amino acid long predicted prodomains, were overexpressed in transgenic banana plants using embryogenic cells as explants for Agrobacterium-mediated genetic transformation. High level constitutive expression of these defensins in elite banana cv. Rasthali led to significant resistance against infection of Fusarium oxysporum f. sp. cubense as shown by in vitro and ex vivo bioassay studies. Transgenic banana lines expressing either of the two defensins were clearly less chlorotic and had significantly less infestation and discoloration in the vital corm region of the plant as compared to untransformed controls. Transgenic banana plants expressing high level of full-length PhDef1 and PhDef2 were phenotypically normal and no stunting was observed. In conclusion, our results suggest that high-level constitutive expression of floral defensins having distinctive prodomains is an efficient strategy for development of fungal resistance in economically important fruit crops like banana.     

Biotechnological potential of antimicrobial peptides from flowers

Flowers represent a relatively unexplored source of antimicrobial peptides of biotechnological potential. This review focuses on flower-derived defense peptide classes with inhibitory activity towards plant pathogens. Small cationic peptides display diverse activities, including inhibition of digestive enzymes and bacterial and/or fungal inhibition. Considerable research is ongoing in this area, with natural crop plant defense potentially improved through the application of transgenic technologies. In this report, comparisons were made of peptide tertiary structures isolated from diverse flower species. A summary is provided of molecular interactions between flower peptides and pathogens, which include the role of membrane proteins and lipids. Research on these peptides is contributing to our understanding of pathogen resistance mechanisms, which will, given the perspectives for plant genetic modification, contribute long term to plant genetic improvement for increased resistance to diverse pathogens.     

Can plant defensins be used to engineer durable commercially useful fungal resistance in crop plants?

Plant defensins are cysteine-rich proteins that play an important role in defense against fungal pathogens. Because of their potent antifungal activity, they have a strong potential to be used for engineering disease resistance in crops. Significant advances have been made in elucidating their structure–activity relationships and modes of antifungal action. Their expression in transgenic plants provides resistance to fungal pathogens in crop plants. In this article, we review recent advances and offer future perspectives on the use of these proteins for engineering durable commercially useful disease resistance in transgenic crop plants.     

Expression of BrD1, a plant defensin from Brassica rapa, confers resistance against brown planthopper (Nilaparvata lugens) in transgenic rices

Plant defensins are small (5-10 kDa) basic peptides thought to be an important component of the defense pathway against fungal and/or bacterial pathogens. To understand the role of plant defensins in protecting plants against the brown planthopper, a type of insect herbivore, we isolated the Brassica rapa Defensin 1 (BrD1) gene and introduced it into rice (Oryza sativa L.) to produce stable transgenic plants. The BrD1 protein is homologous to other plant defensins and contains both an N-terminal endoplasmic reticulum signal sequence and a defensin domain, which are highly conserved in all plant defensins. Based on a phylogenetic analysis of the defensin domain of various plant defensins, we established that BrD1 belongs to a distinct subgroup of plant defensins. Relative to the wild type, transgenic rices expressing BrD1 exhibit strong resistance to brown planthopper nymphs and female adults. These results suggest that BrD1 exhibits insecticidal activity, and might be useful for developing cereal crop plants resistant to sap-sucking insects, such as the brown planthopper.     

硫堇蛋白及细胞防御素在植物抗病性育种中的研究

硫堇蛋白及细胞防御素是一类广泛存在于植物细胞中并对细菌、真菌等病原微生物具有抑制或杀灭作用的小分子量多肽抗生素。二者在分子量、空间结构及某些化学性质具有相似性,近年来在植物抗病性育种中得以应用。对植物硫堇蛋白及细胞防御素的分类、结构、作用机制以及在植物抗性育种的应用实例进行综述。     

Evolutionary relationship between defensins in the Poaceae family strengthened by the characterization of new sugarcane defensins

Plant defensins are small (45-54 amino acids), highly basic, cysteine-rich peptides structurally related to defensins of other organisms, including insects and mammals. Small putative proteins (MW < 10 kDa) containing eight cysteines were screened based on the sugarcane expressed sequence tag (EST) database. We selected ORFs that exhibited 25-100% similarity in primary sequence with other defensins in the NCBI database and that contained eight cysteines. This similarity is sufficient for folding prediction, but not enough for biological activity inference. Six putative defensins (Sd1-6) were selected, and activity assays showed that recombinant Sd1, Sd3 and Sd5 are active against fungi, but not against bacteria. Structural characterization, based on circular dichroism (CD) and nuclear magnetic resonance (NMR) spectroscopy showed that the structures of these Sds were compatible with alpha/beta proteins, a feature expected for plant defensins. Phylogenetic analysis revealed that sugarcane defensins could clearly be grouped within defensins from Poaceae family and Andropogoneae tribe. Our work demonstrates that defensins show strong conservation in the Poaceae family and may indicate that the same conservation occurs in other families. We suggest that evolutionary relationships within plant families can be used as a procedure to predict and annotate new defensins in genomes and group them in evolutionary classes to help in the investigation of their biological function.     

Plant alpha-amylase inhibitors and their interaction with insect alpha-amylases.

Insect pests and pathogens (fungi, bacteria and viruses) are responsible for severe crop losses. Insects feed directly on the plant tissues, while the pathogens lead to damage or death of the plant. Plants have evolved a certain degree of resistance through the production of defence compounds, which may be aproteic, e.g. antibiotics, alkaloids, terpenes, cyanogenic glucosides or proteic, e.g. chitinases, beta-1,3-glucanases, lectins, arcelins, vicilins, systemins and enzyme inhibitors. The enzyme inhibitors impede digestion through their action on insect gut digestive alpha-amylases and proteinases, which play a key role in the digestion of plant starch and proteins. The natural defences of crop plants may be improved through the use of transgenic technology. Current research in the area focuses particularly on weevils as these are highly dependent on starch for their energy supply. Six different alpha-amylase inhibitor classes, lectin-like, knottin-like, cereal-type, Kunitz-like, gamma-purothionin-like and thaumatin-like could be used in pest control. These classes of inhibitors show remarkable structural variety leading to different modes of inhibition and different specificity profiles against diverse alpha-amylases. Specificity of inhibition is an important issue as the introduced inhibitor must not adversely affect the plant's own alpha-amylases, nor the nutritional value of the crop. Of particular interest are some bifunctional inhibitors with additional favourable properties, such as proteinase inhibitory activity or chitinase activity. The area has benefited from the recent determination of many structures of alpha-amylases, inhibitors and complexes. These structures highlight the remarkable variety in structural modes of alpha-amylase inhibition. The continuing discovery of new classes of alpha-amylase inhibitor ensures that exciting discoveries remain to be made. In this review, we summarize existing knowledge of insect alpha-amylases, plant alpha-amylase inhibitors and their interaction. Positive results recently obtained for transgenic plants and future prospects in the area are reviewed.     

Modes of antifungal action and in planta functions of plant defensins and defensin-like peptides

Plant defensins are small basic peptides that are inhibitory against a range of plant and human pathogens. Their in vitro antimicrobial activity and structural similarity with human and insect defensins indicated an important role for plant defensins in the innate immune system of plants. Regarding their mode of antimicrobial action, most plant defensins interact with a specific microbial surface receptor, resulting in microbial cell death via e.g. induction of apoptosis. However, accumulating evidence suggests additional in vivo functions of these plant defensins, and by extension of the more recently discovered defensin-like peptides, in general plant development. In this review we will discuss both, the functional roles of defensins in the plant and their modes of antimicrobial action.     

Interactions of antifungal plant defensins with fungal membrane components

Plant defensins are small, basic, cysteine-rich peptides that are generally active against a broad spectrum of fungal and yeast species at micromolar concentrations. Some of these defensins interact with fungal-specific lipid components in the plasmamembrane. Structural differences of these membrane components between fungal and plant cells probably account for the selective activity of plant defensins against fungal pathogens and their nonphytotoxic properties. This review will focus on different classes of complex lipids in fungal membranes and on the selective interaction of plant defensins with these complex lipids.     

Modes of antifungal action and in planta functions of plant defensins and defensin-like peptides

Plant defensins are small basic peptides that are inhibitory against a range of plant and human pathogens. Their in vitro antimicrobial activity and structural similarity with human and insect defensins indicated an important role for plant defensins in the innate immune system of plants. Regarding their mode of antimicrobial action, most plant defensins interact with a specific microbial surface receptor, resulting in microbial cell death via e.g. induction of apoptosis. However, accumulating evidence suggests additional in vivo functions of these plant defensins, and by extension of the more recently discovered defensin-like peptides, in general plant development. In this review we will discuss both, the functional roles of defensins in the plant and their modes of antimicrobial action.     

Structural analysis of the unique insecticidal activity of novel mungbean defensin VrD1 reveals possibility of homoplasy evolution between plant defensins and scorpion neurotoxins

A variety of evolutionarily related defensin molecules is found in plants and animals. Plant gamma-thionins and scorpion neurotoxins, for instance, may be categorized in this functional group, although each class recognizes a distinct receptor binding site. Such molecules are also categorized into the superfamily of cysteine-rich proteins. Plant defensins were generally believed to be involved in antimicrobial or antifungal mechanisms and, unlike scorpion toxins, little is known about whether these molecules are also endowed with the function of insect resistance. We have previously reported the isolation of a cDNA encoding a small cysteine-rich protein designated VrD1 (VrCRP) from a bruchid-resistant mungbean, which is apparently the first discovered plant defensin exhibiting in vitro and in vivo both insecticidal and antifungal activities. Our previous data also successfully demonstrated that VrD1 is toxic to E. coli and able to completely arrest the growth of Sf-21 insect cells at low concentration. However, the molecular and structural basis of this unique insecticidal activity of VrD1 is not clear. Therefore, in the present study, we use structural approach and phylogenic analysis to investigate the evolutionary and functional relations for such unique insecticidal activity. From our results, it is suggested that VrD1, in addition to gamma-thionins and several amylase inhibitors, is highly homologous to scorpion toxins, especially the short toxins. Moreover, based on the observation from our homology structures, VrD1 may utilize a newly found cluster of basic residues to achieve its insecticidal function, whereas all the other plant gamma-thionins were known to use a previously identified basic cluster conserved for gamma-thionins. Considering the general feature of short scorpion toxins to act on insect cell membranes with K(+)- or Cl(-)-channels as molecular targets, our analysis of interaction and recognition modes provides reasonable correlations between this newly found basic cluster and the insecticidal activity of VrD1, which is also comprehended as a possible link for "homoplasy evolution" between plant and animal defensin molecules.     

Plant defensins and virally encoded fungal toxin KP4 inhibit plant root growth

Plant defensins are small, highly stable, cysteine-rich antimicrobial proteins that are thought to constitute an important component of plant defense against fungal pathogens. There are a number of such defensins expressed in various plant tissues with differing antifungal activity and spectrum. Relatively little is known about the modes of action and biological roles of these proteins. Our previous work on a virally encoded fungal toxin, KP4, from Ustilago maydis and subsequently with the plant defensin, MsDef1, from Medicago sativa demonstrated that some of these proteins specifically blocked calcium channels in both fungi and animals. The results presented here demonstrate that KP4 and three plant defensins, MsDef1, MtDef2, and RsAFP2, all inhibit root growth in germinating Arabidopsis seeds at low micromolar concentrations. We have previously demonstrated that a fusion protein composed of Rab GTPase (RabA4b) and enhanced yellow fluorescent protein (EYFP) is dependent upon calcium gradients for localization to the tips of the growing root hairs in Arabidopsis thaliana. Using this tip-localized fusion protein, we demonstrate that all four proteins rapidly depolarize the growing root hair and block growth in a reversible manner. This inhibitory activity on root and root hair is not directly correlated with the antifungal activity of these proteins and suggests that plants apparently express targets for these antifungal proteins. The data presented here suggest that plant defensins may have roles in regulating plant growth and development. A. Allen and A.K. Snyder contributed equally.     

Constitutive expression of a fusion gene comprising Trigonella foenum-graecum defensin (Tfgd2) and Raphanus sativus antifungal protein (RsAFP2) confers enhanced disease and insect resistance in transgenic tobacco

Plant defensins are small, basic cysteine-rich peptides that can inhibit the growth of a broad range of fungi or bacteria at micro-molar concentrations. They have been introduced as transgenes into different species to enhance host resistance to pathogens. In this study, a fusion gene of two defensins, Trigonella foenum-graecum defensin 2 (Tfgd2) and Raphanus sativus antifungal protein 2 (RsAFP2) fused by a linker peptide of a polyprotein precursor from Impatiens balsamina was introduced into tobacco (Nicotiana tabacum var. Xanthi) via Agrobacterium-mediated leaf section transformation. Putative transgenic plants were confirmed by PCR analysis and integration of the fusion gene was confirmed by Southern blotting. RT-PCR analysis showed that the fusion gene was expressed in several confirmed transgenic plants. Western blotting analysis of crude protein extracts from leaves of the transgenic plants with anti-Tfgd2 and anti-RsAFP2 antibodies exhibited an 8 and 9 kDa bands corresponding to size of the fusion gene and confirmed the expression of fusion protein. When the leaves of transgenic plants were challenged with Rhizoctonia solani and Phytophthora parasitica var. nicotianae pathogens, they showed enhanced levels of disease resistance along with resistance to the generalist herbivore, Spodoptera litura larvae compared to control. Our results demonstrate that Tfgd2–RsAFP2 fusion protein is effective in protecting the transgenic plants against fungal and insect pathogens.     

Peptide promiscuity: an evolutionary concept for plant defense

The phenomenon of protein promiscuity, in which multiple functions are associated with a single peptide structure, has gained attention in several research fields, including the plant defense field. With this in mind, this report intends to link various plant defense peptides with common scaffolds (defensins, cyclotides and 2S albumins), and multiple activities with the processes of promiscuity generation and protein evolvability. This link seems to create an efficient system of plant defense against insect pests and pathogens, and is thus essential to plant survival and evolution. This review also identifies future possibilities for the use of peptide promiscuity in designing novel drugs and synthetic biotechnological products.     

Defense peptides of plant immunity

Antimicrobial peptides (AMPs) are natural antibiotics produced by all living organisms to fight pathogens. They are important effector molecules of the immune system both in animals and plants. AMPs are diverse in structure and mode of action. Based on the homology of amino acid sequences and 3D structures several AMP families have been distinguished. They are defensins, thionins, lipid transfer proteins, hevein- and knottin-like peptides, and cyclotides. AMPs display broad-spectrum antimicrobial activity and thus show promise for the development of disease-resistant crops by genetic engineering and for the production of new-generation drugs. In this paper, the properties of the main AMP families (defensins and hevein-like peptides) and of new 4-Cys plant AMP family are reviewed.