Tomato prosystemin promoter confers wound-inducible, vascular bundle-specific expression of the β-glucuronidase gene in transgenic tomato plants

Tomato (Lycopersicon esculentum Mill. cv. Better Boy) plants were transformed with a fused gene containing a 2.2-kb promoter fragment of the tomato prosystemin gene and the coding region of the β-glucuronidase (GUS) reporter gene. The transgenic plants exhibited a low constitutive level of prosystemin-β-glucuronidase gene expression, assayed by histochemical staining and GUS enzyme activity, that was associated in the vascular bundles of leaf main veins, petiolules, petioles and stems. The GUS activity in the vascular bundles in each tissue was increased by wounding and by treatment of the plants with methyl jasmonate, similar to the induction of prosystemin in wild-type plants. The increase in GUS activity in the vascular bundles of leaves in response to wounding correlated with the wound-inducible increase in prosystemin mRNA. Tissue printing, using rabbit anti-serum prepared against prosystemin, confirmed that inducible prosystemin protein was localized in vascular bundles of petiolules, petioles and stems of wild-type tomato plants. The evidence indicates that the 2.2-kb promoter region of the tomato prosystemin gene contains elements conferring its correct temporal and spatial expression in the vascular bundles of transgenic tomato plants. Received: 7 January 1997 / Accepted: 2 April 1997     

Intraspecific variation in a generalist herbivore accounts for differential induction and impact of host plant defences

Plants and herbivores are thought to be engaged in a coevolutionary arms race: rising frequencies of plants with anti-herbivore defences exert pressure on herbivores to resist or circumvent these defences and vice versa. Owing to its frequency-dependent character, the arms race hypothesis predicts that herbivores exhibit genetic variation for traits that determine how they deal with the defences of a given host plant phenotype. Here, we show the existence of distinct variation within a single herbivore species, the spider mite Tetranychus urticae, in traits that lead to resistance or susceptibility to jasmonate (JA)-dependent defences of a host plant but also in traits responsible for induction or repression of JA defences. We characterized three distinct lines of T. urticae that differentially induced JA-related defence genes and metabolites while feeding on tomato plants (Solanum lycopersicum). These lines were also differently affected by induced JA defences. The first line, which induced JA-dependent tomato defences, was susceptible to those defences; the second line also induced JA defences but was resistant to them; and the third, although susceptible to JA defences, repressed induction. We hypothesize that such intraspecific variation is common among herbivores living in environments with a diversity of plants that impose diverse selection pressure.     

A herbivore that manipulates plant defence

Phytopathogens and herbivores induce plant defences. Whereas there is evidence that some pathogens suppress these defences by interfering with signalling pathways involved in the defence, such evidence is scarce for herbivores. We found that the invasive spider mite Tetranychus evansi suppresses the induction of the salicylic acid and jasmonic acid signalling routes involved in induced plant defences in tomato. This was reflected in the levels of inducible defence compounds, such as proteinase inhibitors, which in mite-infested plants were reduced to even lower levels than the constitutive levels in herbivore-free plants. Additionally, the spider mite suppressed the release of inducible volatiles, which are implicated in plant defence. Consequently, the mites performed much better on previously attacked plants than on non-attacked plants. These findings provide a new perspective on plant-herbivore interactions, plant protection and plant resistance to invasive species.     

Systemic wound signaling in tomato leaves is cooperatively regulated by systemin and hydroxyproline-rich glycopeptide signals

Hydroxyproline-rich glycopeptides (HypSys peptides) have been isolated recently from tobacco and tomato leaves that are powerful activators of protease inhibitor synthesis. The peptides are processed from polyprotein precursors, two from a single tobacco precursor and three from a single tomato precursor. The precursor genes are expressed in response to wounding and methyl jasmonate, similar to the expression of the systemin precursor prosystemin in tomato leaves. Here we investigate the relationships between systemin and the tomato HypSys peptides in regulating wound signaling in tomato plants. Analysis of transgenic tomato plants over-expressing sense and antisense constructs of the tomato HypSys precursor under the 35S CaMV promoter show that the transgenic plants regulate protease inhibitor gene expression in response to wounding in a manner similar to prosystemin. The evidence indicates that the expression of both the tomato HypSys precursor gene and the prosystemin gene in response to wounding are necessary for strong systemic signaling. The data supports a role for both genes in an amplification loop that up-regulates the octadecanoid pathway and the synthesis of jasmonates to effect strong systemic signaling of defense genes. This report provides the first demonstration of the involvement of two plant peptides derived from two unrelated genes in regulating long distance wound signaling in plants. The author responsible for distribution of materials integral to the findings presented in this article in accordance with the policy described in the Instructions for Authors () is Clarence A. Ryan.     

Tracing the history of plant traits under domestication in cranberries: potential consequences on anti-herbivore defences

The process of selecting certain desirable traits for plant breeding may compromise other potentially important traits, such as defences against pests; however, specific phenotypic changes occurring over the course of domestication are unknown for most domesticated plants. Cranberry (Vaccinium macrocarpon) offers a unique opportunity to study such changes: its domestication occurred recently, and we have access to the wild ancestors and intermediate varieties used in past crosses. In order to investigate whether breeding for increased yield and fruit quality traits may indirectly affect anti-herbivore defences, the chemical defences have been examined of five related cranberry varieties that span the history of domestication against a common folivore, the gypsy moth (Lymantria dispar). Direct defences were assessed by measuring the performance of gypsy moth caterpillars and levels of phenolic compounds in leaves, and indirect defences by assaying induced leaf volatile emissions. Our results suggest that breeding in cranberry has compromised plant defences: caterpillars performed best on the derived NJS98-23 (the highest-yielding variety) and its parent Ben Lear. Moreover, NJS98-23 showed reduced induction of volatile sesquiterpenes, and had lower concentrations of the defence-related hormone cis-jasmonic acid (JA) than ancestral varieties. However, induced direct defences were not obviously affected by breeding, as exogenous JA applications reduced caterpillar growth and increased the amounts of phenolics independent of variety. Our results suggest that compromised chemical defences in high-yielding cranberry varieties may lead to greater herbivore damage which, in turn, may require more intensive pesticide control measures. This finding should inform the direction of future breeding programmes.     

The expression of tomato prosystemin gene in tobacco plants highly affects host proteomic repertoire

Systemin, an octadecapeptide isolated from tomato, is a primary signal molecule involved in the local and systemic responses to pest attack, elicited by activation of a set of defence genes. It derives from processing of prosystemin, a prohormone of almost 200 amino acids. Prosystemin orthologues have been found in other Solanaceae species but not in tobacco, where are present hydroxyproline-rich peptides functionally but not structurally related to tomato systemin. Molecular events leading to the release of signalling peptides from protein precursors are unknown in plants; the occurrence of a family of signal molecules suggests that initiation of wound response may involve different processing mechanisms. It has been previously shown that the protein product from an engineered tomato prosystemin gene is processed in tobacco, thus suggesting that the components responsible for its post-translational modifications are present in this species. By analyzing analysing the proteome repertoire of transformed tobacco plant leaves with 2-DE, here we demonstrate that the constitutive expression of the tomato prosystemin gene highly affected host protein synthesis. In particular, engineered plants showed a number of differentially synthesized proteins that were identified by PMF MALDI-TOF and microLC-ESI-IT-MS/MS experiments as polypeptide species involved in protection from pathogens and oxidative stress, or in carbon/energy metabolism. Significant differences in over-produced proteins were observed with respect to previous data reported on systemin-engineered tomato plants. Our results strongly support the need of using proteomic approaches during systematic analysis of plant tissues to investigate the principle of substantial equivalence in transgenic plants expressing a transgene coding for a signalling molecule.     

87 kDa tomato cystatin exhibits properties of a defense protein and forms protein crystals in prosystemin overexpressing transgenic plants

Transgenic tomato plants (Lycopersicon esculentum) overexpressing the prosystemin transgene have been shown previously to accumulate a soluble 87 kDa cystatin constitutively. We report here that this protein can be found in a crystalline form which can be purified using a glycerol/sucrose gradient. Midgut homogenate of third-instar larvae of two coleopteran pest insects, Callosobruchus maculatus and Zabrotes subfasciatus, had their proteolytic activity content significantly inhibited by tomato cystatin (TC). In leaves of wild-type tomato plants, cystatin mRNA accumulated systemically in response to wounding, treatment with methyl jasmonate (MJ) and when supplied with systemin, corroborating the anti-herbivorous activity. Accumulation of cystatin mRNA occurred when plants were supplied with chitosan and oligogalacturonic acid fragments (OGA), suggesting an effect of TC against pathogens. Moreover, this protein reduced the growth of two fungi, Fusarium solani and Trichoderma viride in vitro. Taken together, the data reinforce a role for TC in defense response against pests or pathogens.     

Salt stress activation of wound-related genes in tomato plants

Plants respond to various stresses by expressing distinct sets of genes. The effects of multiple stresses on plants and their interactions are not well understood. We have discovered that salt stress causes the accumulation of proteinase inhibitors and the activation of other wound-related genes in tomato (Lycopersicon esculentum) plants. Salt stress was also found to enhance the plant's response to wounding locally and systemically. The tomato mutant (def-1), which has an impairment in the octadecanoid pathway, displayed a severe reduction in the accumulation of proteinase inhibitors under salt stress, indicating that salt stress-induced accumulation of proteinase inhibitors was jasmonic acid dependent. The analysis of salt stress in another tomato mutant, spr-1, which carries a mutation in a systemin-specific signaling component, and transgenic tomato plants that express an antisense-prosystemin cDNA, showed that prosystemin activity was not required for the salt-induced accumulation of proteinase inhibitors, but was necessary to achieve maximal levels. These results suggest that a prosystemin independent- but jasmonic acid-dependent pathway is utilized for proteinase inhibitor accumulation in response to salt stress.     

Prosystemin-antimicrobial-peptide fusion reduces tomato late blight lesion expansion

Antimicrobial peptides offer a new method for controlling pathogens, however, many promising peptides are too small for direct production in plants. A protein delivery system was developed based on a proteolytic mechanism used by Solanaceous plants to produce the very small (18 amino acid) signaling peptide systemin from the polypeptide prosystemin. Fusion of the gene encoding the 23 kDa protein prosystemin with the antimicrobial peptide (pep11) sequence, replacing the systemin sequence, allowed for expression in transgenic tomato plants. Six days after inoculation with the late blight pathogen Phytophthora infestans, detached leaflets of transgenic tomato (Rutgers) exhibited a reduction in lesion size of at least 50 percent.     

The cellular localization of prosystemin: a functional role for phloem parenchyma in systemic wound signaling

The systemin precursor, prosystemin, has been previously shown to be sequestered in vascular bundles of tomato (Lycopersicon esculentum Mill.) plants, but its subcellular compartmentalization and association with a specific cell type has not been established. We present in situ hybridization and immunocytochemical evidence at the light, confocal, and transmission electron microscopy levels that wound-induced and methyl jasmonate-induced prosystemin mRNA and protein are exclusively found in vascular phloem parenchyma cells of minor veins and midribs of leaves, and in the bicollateral phloem bundles of petioles and stems of tomato. Prosystemin protein was also found constitutively in parenchyma cells of various floral organs, including sepals, petals and anthers. At the subcellular level, prosystemin was found compartmentalized in the cytosol and the nucleus of vascular parenchyma cells. The cumulative data indicate that vascular phloem parenchyma cells are the sites for the synthesis and processing of prosystemin as a first line of defense signaling in response to herbivore and pathogen attacks.Abbreviations IgG immunoglobulin - TEM transmission electron microscope     

Induced defences alter the strength and direction of natural selection on reproductive traits in common milkweed

Evolutionary biologists have long sought to understand the ecological processes that generate plant reproductive diversity. Recent evidence indicates that constitutive antiherbivore defences can alter natural selection on reproductive traits, but it is unclear whether induced defences will have the same effect and whether reduced foliar damage in defended plants is the cause of this pattern. In a factorial field experiment using common milkweed, Asclepias syriaca L., we induced plant defences using jasmonic acid (JA) and imposed foliar damage using scissors. We found that JA‐induced plants experienced selection for more inflorescences that were smaller in size (fewer flowers), whereas control plants only experienced a trend towards selection for larger inflorescences (more flowers); all effects were independent of foliar damage. Our results demonstrate that induced defences can alter both the strength and direction of selection on reproductive traits, and suggest that antiherbivore defences may promote the evolution of plant reproductive diversity.     

Characterization of prosystemin expressed in the baculovirus/insect cell system reveals biological activity of the systemin precursor

 Tomato (Lycopersicon esculentum Mill.) prosystemin in fusion with a viral signal peptide was expressed in Sf21 insect cell cultures after infection with recombinant baculoviruses. Prosystemin was purified from culture supernatants and its identity was confirmed by N-terminal sequence and mass-spectral analyses. Recombinant prosystemin was found to be equally active as compared to systemin in inducing the expression of wound-response genes in tomato plants. In cultured cells of L. peruvianum, prosystemin elicited a rapid alkalinization of the growth medium. The timing and dose-dependence of the alkalinization response were found to be identical for prosystemin and systemin, respectively. Prosystemin-triggered defense responses were inhibited by a competitive antagonist of systemin activity, indicating that the systemin sequence within the primary structure of prosystemin determines its activity. Received: 30 August 1999 / Accepted: 6 December 1999     

Wound- and systemin-inducible calmodulin gene expression in tomato leaves

Using a calmodulin (CaM) cDNA as a probe in northern analyses, transgenic tomato plants that overexpress the prosystemin gene were found to express increased levels of CaM mRNA and protein in leaves compared to wild-type plants. These transgenic plants have been reported previously to express several wound-inducible defense-related genes in the absence of wounding. Calmodulin mRNA and protein levels were found to increase in leaves of young wild-type tomato plants after wounding, or treatment with systemin, methyl jasmonate, or linolenic acid. CaM mRNA appeared within 0.5 h after wounding or supplying young tomato plants with systemin, and peaked at 1 h. The timing of CaM gene expression is similar to the expression of the wound- or systemin-induced lipoxygenase and prosystemin genes, signal pathway genes whose expression have been reported to begin at 0.5–1 h after wounding and 1–2 h earlier than the genes coding for defensive proteinase inhibitor genes. The similarities in timing between the synthesis of CaM mRNA and the mRNAs for signal pathway components suggests that CaM gene expression may be associated with the signaling cascade that activates defensive genes in response to wounding.     

Constitutive salicylic acid defences do not compromise seed yield,drought tolerance and water productivity in the Arabidopsis accession C24

Plants that constitutively express otherwise inducible disease resistance traits often suffer a depressed seed yield in the absence of a challenge by pathogens. This has led to the view that inducible disease resistance is indispensable, ensuring that minimal resources are diverted from growth, reproduction and abiotic stress tolerance. The Arabidopsis genotype C24 has enhanced basal resistance, which was shown to be caused by permanent expression of normally inducible salicylic acid (SA)‐regulated defences. However, the seed yield of C24 was greatly enhanced in comparison to disease‐resistant mutants that display identical expression of SA defences. Under both water‐replete and ‐limited conditions, C24 showed no difference and increased seed yield, respectively, in comparison with pathogen‐susceptible genotypes. C24 was the most drought‐tolerant genotype and showed elevated water productivity, defined as seed yield per plant per millilitre water consumed, and achieved this by displaying adjustments to both its development and transpiration efficiency (TE). Therefore, constitutive high levels of disease resistance in C24 do not affect drought tolerance, seed yield and seed viability. This study demonstrates that it will be possible to combine traits that elevate basal disease resistance and improve water productivity in crop species, and such traits need not be mutually exclusive.     

Positional specificity of a phospholipase A activity induced by wounding, systemin, and oligosaccharide elicitors in tomato leaves

Phospholipase A (PLA) activity, as measured by the accumulation of (14)C-lysophosphatidylcholine in leaves of tomato plants, increased rapidly and systemically in response to wounding. The increase in PLA activity in the systemic unwounded leaves was biphasic in wild-type tomato plants, peaking at 15 min and again at 60 min, but the second peak of activity was absent in transgenic prosystemin antisense plants. Supplying young excised tomato plants with the polypeptide hormone systemin also caused (14)C-lysophosphatidylcholine to increase to levels similar to those induced by wounding, but the increase in activity persisted for >2 hr. Antagonists of systemin blocked both the release of (14)C-lysophosphatidylcholine and the accumulation of defense proteins in response to systemin. (14)C-lysophosphatidylcholine levels did not increase in response to jasmonic acid. Chemical acylation of the lysophosphatidylcholine produced by wounding, systemin, and oligosaccharide elicitors followed by enzymatic hydrolysis with lipases of known specificities demostrated that the lysophosphatidylcholine is generated by a PLA with specificity for the sn-2 position.