Wound-induced trypsin inhibitor in alfalfa leaves: identity as a member of the Bowman-Birk inhibitor family

The primary structure of the wound-inducible trypsin inhibitor from alfalfa (ATI) establishes it as a member of the Bowman-Birk proteinase inhibitor family. The time course of induction of ATI in alfalfa following wounding is similar to the induction of the nonhomologous proteinase inhibitors I and II in tomato and potato leaves, and, like inhibitors I and II, ATI is induced to accumulate in excised leaves supplied with the proteinase inhibitor inducing factor from tomato leaves. The similarity of the wound induction of ATI to that of inhibitors I and II indicates that wound-regulated systems are present in Solanaceae and Leguminosae plant families that possess a common fundamental recognition system regulating synthesis of proteinase inhibitors in response to pest attacks. ATI is the first Bowman-Birk inhibitor that has been found in leaves and is the only member of this family known to be regulated by wounding.     

Molecular biology of wound-inducible proteinase inhibitors in plants

Abstract. The techniques of molecular biology are being employed to investigate at the gene level the systemically mediated, wound-induced accumulation of two defensive proteinase inhibitor proteins in plant leaves. These techniques have added a new dimension to biochemical and physiological studies already underway to understand the mechanism of induction by wounding. The acquisition of cDNAs from the RNAs coding for the two inhibitors facilitated studies of mRNA synthesis in leaves in response to wounding, and provided probes to obtain wound-inducible proteinase inhibitor genes from tomato ( Lycopersicon esculentum ) and potato (Solarium tuberosum) genomes. Successful transformations of tobacco plants with fused genes, containing the 5' and 3' regions of the inhibitor genes with the open reading frame of the chloramphenicol acelyltransferase ( cat ) gene, have provided a wound-inducible chloramphenicol acetyltransferase (CATase) activity with which to seek cis- and transacting elements that regulate wound-inducibility to help to understand the interaction of cytoplasmic and nuclear components of the intracellular communication systems that activate the proteinase inhibitor genes in response to wounding by insect pests.     

Hydrogen peroxide acts as a second messenger for the induction of defense genes in tomato plants in response to wounding, systemin, and methyl jasmonate

The systemic accumulation of both hydrogen peroxide (H(2)O(2)) and proteinase inhibitor proteins in tomato leaves in response to wounding was inhibited by the NADPH oxidase inhibitors diphenylene iodonium (DPI), imidazole, and pyridine. The expression of several defense genes in response to wounding, systemin, oligosaccharides, and methyl jasmonate also was inhibited by DPI. These genes, including those of four proteinase inhibitors and polyphenol oxidase, are expressed within 4 to 12 hr after wounding. However, DPI did not inhibit the wound-inducible expression of genes encoding prosystemin, lipoxygenase, and allene oxide synthase, which are associated with the octadecanoid signaling pathway and are expressed 0.5 to 2 hr after wounding. Accordingly, treatment of plants with the H(2)O(2)-generating enzyme glucose oxidase plus glucose resulted in the induction of only the later-expressed defensive genes and not the early-expressed signaling-related genes. H(2)O(2) was cytochemically detected in the cell walls of vascular parenchyma cells and spongy mesophyll cells within 4 hr after wounding of wild-type tomato leaves, but not earlier. The cumulative results suggest that active oxygen species are generated near cell walls of vascular bundle cells by oligogalacturonide fragments produced by wound-inducible polygalacturonase and that the resulting H(2)O(2) acts as a second messenger for the activation of defense genes in mesophyll cells. These data provide a rationale for the sequential, coordinated, and functional roles of systemin, jasmonic acid, oligogalacturonides, and H(2)O(2) signals for systemic signaling in tomato plants in response to wounding.     

Isolation of signaling mutants of tomato (Lycopersicon esculentum)

As a first step towards developing a genetic system for investigating signaling processes in plants, we have developed a screen for signaling mutants deficient in a wound response. We have isolated two mutants of tomato that lack detectable production of proteinase inhibitors induced systemically in leaves by wounding. The mutants are deficient in the induction of both proteinase Inhibitor I and proteinase Inhibitor II but can be induced to respond at near wild-type levels by methyl jasmonate, a known elicitor of inhibitor production in tomato. While completely deficient in systemic production of proteinase inhibitors, both mutants produce some proteinase inhibitor in wounded leaves. This evidence suggests the existence of two signaling pathways, one local and one systemic, that regulate the induction of proteinase inhibitor snythesis in response to wounding.     

Isolation of signaling mutants of tomato (Lycopersicon esculentum)

As a first step towards developing a genetic system for investigating signaling processes in plants, we have developed a screen for signaling mutants deficient in a wound response. We have isolated two mutants of tomato that lack detectable production of proteinase inhibitors induced systemically in leaves by wounding. The mutants are deficient in the induction of both proteinase Inhibitor I and proteinase Inhibitor II but can be induced to respond at near wild-type levels by methyl jasmonate, a known elicitor of inhibitor production in tomato. While completely deficient in systemic production of proteinase inhibitors, both mutants produce some proteinase inhibitor in wounded leaves. This evidence suggests the existence of two signaling pathways, one local and one systemic, that regulate the induction of proteinase inhibitor snythesis in response to wounding.     

Nitric oxide negatively modulates wound signaling in tomato plants

Synthesis of proteinase inhibitor I protein in response to wounding in leaves of excised tomato (Lycopersicon esculentum) plants was inhibited by NO donors sodium nitroprusside and S-nitroso-N-acetyl-penicillamine. The inhibition was reversed by supplying the plants with the NO scavenger 2-(4-carboxiphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide. NO also blocked the hydrogen peroxide (H(2)O(2)) production and proteinase inhibitor synthesis that was induced by systemin, oligouronides, and jasmonic acid (JA). However, H(2)O(2) generated by glucose oxidase and glucose was not blocked by NO, nor was H(2)O(2)-induced proteinase inhibitor synthesis. Although the expression of proteinase inhibitor genes in response to JA was inhibited by NO, the expression of wound signaling-associated genes was not. The inhibition of wound-inducible H(2)O(2) generation and proteinase inhibitor gene expression by NO was not due to an increase in salicylic acid, which is known to inhibit the octadecanoid pathway. Instead, NO appears to be interacting directly with the signaling pathway downstream from JA synthesis, upstream of H(2)O(2) synthesis. The results suggest that NO may have a role in down-regulating the expression of wound-inducible defense genes during pathogenesis.     

A novel function for the cathepsin D inhibitor in tomato

Proteinaceous aspartic proteinase inhibitors are rare in nature and are described in only a few plant species. One of them corresponds to a family of cathepsin D inhibitors (CDIs) described in potato (Solanum tuberosum), involving up to 15 isoforms with a high sequence similarity. In this work, we describe a tomato (Solanum lycopersicum) wound-inducible protein called jasmonic-induced protein 21 (JIP21). Sequence analysis of its cDNA predicted a putative function as a CDI. The JIP21 gene, whose protein has been demonstrated to be glycosylated, is constitutively expressed in flowers, stem, and fruit, and is inducible to high levels by wounding and methyl jasmonate in leaves of tomato plants. The genomic sequence of JIP21 shows that the gene is intronless and reveals the presence of both a methyl jasmonate box (TGACT) and a G-box (CACGT) in the promoter. In contrast to the presumed role of JIP21 based on sequence analysis, a detailed biochemical characterization of the purified protein uncovers a different function as a strong chymotrypsin inhibitor, which questions the previously predicted inhibitory activity against aspartic proteinases. Moreover, Egyptian cotton worm (Spodoptera littoralis) larvae fed on transgenic tomato plants overexpressing JIP21 present an increase in mortality and a delay in growth when compared with larvae fed on wild-type plants. These larvae belong to the Lepidoptera family whose main digestive enzymes have been described as being Ser proteases. All these results support the notion that tomato JIP21 should be considered as a chymotrypsin inhibitor belonging to the Ser proteinase inhibitors rather than a CDI. Therefore, we propose to name this protein tomato chymotrypsin inhibitor 21 (TCI21).     

Differential expression of tomato proteinase inhibitor I and II genes during bacterial pathogen invasion and wounding

Expression of proteinase inhibitor I and II genes was investigated during infection by Pseudomonas syringae pv. tomato, the causal agent of bacterial speck disease in tomato. Inoculation of leaves with P. s. pv. tomato of two inbred tomato lines that are resistant and susceptible to the pathogen resulted in the accumulation of proteinase inhibitor I and II mRNAs in this organ. Our data showed that in the lines used in this study, proteinase inhibitor II mRNAs accumulated in leaves to higher levels than proteinase inhibitor I mRNA in response to P. s. pv. tomato infection and wounding. Proteinase inhibitor II mRNAs accumulated more rapidly in disease-resistant than in disease-susceptible plants. Proteinase inhibitor I mRNAs were first detected in the disease-susceptible line during infection and wounding. In contrast to wounding, the systemic induction of these genes during pathogen ingression was limited. These data show that the plant proteinase inhibitors constitute one of the components of the plant defense system that are induced in response to bacterial pathogen invasion.     

Characterization of two proteinase inhibitor (ATI) cDNAs from alfalfa leaves (Medicago sativa var. Vernema): the expression of ATI genes in response to wounding and soil microorganisms

cDNAs encoding two Bowman-Birk proteinase inhibitors were isolated from the leaves of alfalfa (Medicago sativa). The cDNAs are derived from a small gene family (3 to 10 genes) encoding alfalfa trypsin inhibitors (ATIs). Each cDNA clone encoded a mature ATI that was part of a larger, putative preprotein. ATI mRNAs are continuously expressed in flower parts, but are mechanically wound-inducible in the stems and leaves. ATI mRNA is shown to be continuously present in roots of soil-grown plants, but its presence is primarily in response to microorganisms present in the soil. Additionally, while mechanical wounding of the alfalfa roots induced ATI mRNA synthesis both in the roots and in the leaves, microbial infection of the roots triggered ATI mRNA synthesis in the roots but not in the leaves. These results suggest that both local and systemic signalling pathways for proteinase inhibitor synthesis are present in alfalfa plants.     

Nucleotide sequence of proteinase inhibitor II encoding cDNA of potato (Solanum tuberosum) and its mode of expression

Summary Two cDNA clones containing the complete coding region of a developmentally controlled (tuber-specific) as well as environmentally inducible (wound-inducible) gene from potato (Solanum tuberosum) have been sequenced. The open reading frame codes for 154 amino acids. Its sequence is highly homologous to the proteinase inhibitor II from tomato, indicating that the cDNA's encode the corresponding proteinase inhibitor II of potato. In addition the putative potato proteinase inhibitor II contains a sequence which is completely homologous with that of another small peptide proteinase inhibitor from potato, called PCI-I. Evidence is presented that this small peptide is probably derived from the proteinase inhibitor II by posttranslational processing.Northern type experiments using RNA from wounded and nonwounded leaves demonstrate that RNA homologous to the putative proteinase inhibitor II cDNA's accumulates in leaves as a consequence of wounding, whereas normally the expression of this gene is under strict developmental control, since it is detected only in tubers of potato (Rosahl et al. 1986). In addition the induction of this gene in leaves can also be achieved by the addition of different polysaccharides such as poly galacturonic acid or chitosan. In contrast to the induction of its expression by wounding in leaves, wounding of tubers results in a disappearance of the proteinase II inhibitor m-RNA from these organs.     

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.     

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.     

A Sulfhydryl Reagent Modulates Systemic Signaling for Wound-Induced and Systemin-Induced Proteinase Inhibitor Synthesis

The sulfhydryl group reagent p-chloromecuribenzene sulfonic acid (PCMBS), an established inhibitor of active apoplastic phloem loading of sucrose in several plant species, is shown to be a powerful inhibitor of wound-induced and systemin-induced activation of proteinase inhibitor synthesis and accumulation in leaves of tomato plants (Lycopersicon esculentum cv Castlemart). PCMBS, supplied to young tomato plants through their cut stems, blocks accumulation of proteinase inhibitors in leaves in response to wounding. The application of systemin directly to fresh wounds enhances systemic accumulation of proteinase inhibitors to levels higher than wounding alone. Placed on fresh wounds, PCMBS severely inhibits systemic induction of proteinase inhibitors, in both the presence and absence of exogenous systemin. PCMBS inhibition can be reversed by cysteine, dithiothreitol, and glutathione. Radiolabeled systemin placed on fresh wounds is readily transported from the wounded leaves to upper leaves. However, in the presence of PCMBS, radiolabeled systemin is not transported away from wound sites. Induction of proteinase inhibitor I synthesis by oligouronides (degree of polymerization [almost equal to] 20), linolenic acid, or methyl jasmonate was not inhibited by PCMBS. The cumulative data support a possible role for sulfhydryl groups in mediating the translocation of systemin from wound sites to distal receptor sites in tomato plants and further support a role for systemin as a systemic wound signal.     

Regulation of expression of a wound-inducible tomato inhibitor I gene in transgenic nightshade plants

A wound-inducible proteinase Inhibitor I gene from tomato containing 725 bp of the 5 region and 2.5 kbp of the 3 region was stably incorporated into the genome of black nightshade plants (Solanum nigrum) using an Agrobacterium Ti plasmid-derived vector. Transgenic nightshade plants were selected that expressed the tomato Inhibitor I protein in leaf tissue. The leaves of the plants contained constitutive levels of the inhibitor protein of up to 60 g/g tissue. These levels increased by a factor of about two in response to severe wounding. Only leaves and petioles exhibited the presence of the inhibitor, indicating that the gene exhibited the same tissue specificity of expression found in situ in wounded tomato leaves. Inhibitor I was extracted from leaves of wounded transformed nightshade plants and was partially purified by affinity chromatography on a chymotrypsin-Sepharose column. The affinity-purified protein was identical to the native tomato Inhibitor I in its immunological reactivity and in its inhibitory activity against chymotrypsin. The protein exhibited the same M _r of 8 kDa as the native tomato Inhibitor I and its N-terminal amino acid sequence was identical to that of the native tomato inhibitor I, indicating that the protein was properly processed in nightshade plants. These expriments are the first report of the expression of a member of the wound-inducible tomato Inhibitor I gene family in transgenic plants. The results demonstrate that the gene contains elements that can be regulated in a wound-inducible, tissuespecific manner in nightshade plants.     

Author index for volume 219

Proteinase inhibitors I and II were purified to electrophoretic homogeneity from leaves of tomato plants induced by either wounding intact plants or by supplying excised plants with the proteinase inhibitor inducing factor. Affinity chromatography with chymotrypsin-Sepharose was employed as a final purification step for each inhibitor. The tomato leaf inhibitors are very similar to potato tuber inhibitors I and II in subunit molecular weight, composition, and inhibitory activities against chymotrypsin, trypsin, and subtilisin. However, unlike the potato tuber which contains multiple isoinhibitors by isoelectric focusing, the tomato leaf exhibits only two isoinhibitor forms of inhibitor I and a single form of inhibitor II. The molecular weight of native potato inhibitor I was reevaluated by rigorous ultracentrifugal analysis and compared with data from previous analyses. The data confirm that native inhibitor I has a native M_r of about 41,000 and is a pentamer. Inhibitor II has a molecular weight of near 23,000 and is a dimer.     

Immunological Identification of Proteinase Inhibitors I and II in Isolated Tomato Leaf Vacuoles

Proteinase inhibitor I has been identified and quantified in isolated vacuoles from tomato (Lycopersicon esculentum) leaves induced to accumulate inhibitors either by wounding or by supplying excised leaves with the wound hormone, proteinase inhibitor-inducing factor. Proteinase inhibitor II was also identified in the vacuoles but not quantified. Control vacuoles were prepared from unwounded plants that did not contain inhibitors. Vacuole to leaf cell ratios of inhibitors, chlorophyll, and several vacuolar and cytoplasmic enzymes were determined. The inhibitors were found almost entirely in the vacuoles. Acid phosphatase was located in control leaf vacuoles, but was found in both vacuoles and cytoplasm in induced leaves. Carboxypeptidase, induced by wounding, was found distributed between the vacuoles and cytoplasm of induced leaves. Low vacuole to leaf cell ratios of three cytoplasmic markers, triosephosphate isomerase, catalase, and chlorophyll, indicated that the isolated vacuoles were relatively free of intact protoplasts and cell debris.     

Wound-inducible proteinase inhibitors in pepper. Differential regulation upon wounding, systemin, and methyl jasmonate

Seven small (approximately 6,000 D) wound-inducible proteinase inhibitor proteins were isolated from leaves of pepper (Capsicum annuum) plants that are members of the potato inhibitor II family. N-terminal sequences obtained indicated that the pepper leaf proteinase inhibitors (PLPIs) exhibit homology to two GenBank accessions that code for preproteins containing three isoinhibitors domains each that, when post-translationally processed, can account for the mixture of isoinhibitors that are reported herein from pepper leaves. A constitutive level of PLPI proteins was found in pepper leaves, and these levels increased up to 2.6-fold upon wounding of the lower leaves. Exposing intact plants to methyl jasmonate vapors induced the accumulation of PLPIs. Supplying excised young pepper plants with water through the cut stems induced PLPI proteins to levels higher than those found in intact plants, but with high variability. Supplying the excised plants with systemin did not result in an increase of PLPI levels that were statistically higher than levels found in excised plants. Gel-blot analyses of PLPI induction revealed the presence of two mRNA bands, having slightly different mobilities in agarose gels. Only the low M(r) mRNA is present in untreated control plants, and it appears to be responsible for the constitutive levels of PLPI found in leaves. Both mRNA species are wound- and methyl jasmonate-inducible. Only the low- M(r) species is weakly induced by systemin, indicating a differential expression of the two PLPI species.     

Tobacco proteinase inhibitor I genes are locally,but not systemically induced by stress

A cDNA library of tobacco mosaic virus (TMV)-infected tobacco was screened with polymerase chain reaction products obtained using a degenerate primer corresponding to proteinase inhibitor I (PI-I) of tomato and potato. The resulting clones encoded two highly similar, putative tobacco PI-I proteins, indicating that both genes identified in tobacco are probably expressed. The tobacco PI-I's were approximately 50% identical to wound-inducible potato and tomato PI-I and 80% identical to an ethylene-regulated tomato PI-I. Northern blot analyses indicated that healthy tobacco leaf contains only minor amounts of PI-I mRNA, and that the inhibitor genes are induced by TMV infection, salicylate treatment, ethephon spraying, UV light irradiation and wounding. The results indicate that the tobacco PI-I genes are coordinately expressed with the genes for the basic pathogenesis-related proteins. Contrary to PI-I genes of tomato and potato, wound induction of the tobacco genes occurs only locally; the upper, unwounded leaves do not show any wound-induced PI-I gene expression.     

Gibberellins regulate the abundance of RNAs with sequence similarity to proteinase inhibitors, dioxygenases and dehydrogenases

In an effort to understand the molecular mechanism of gibberellin (GA) action, we have cloned and performed an initial characterization of three cDNAs (GAD1, 2, and 3) which correspond to RNAs that become less abundant by 2 h after treatment of tomato (Lycopersicon esculentum Mill.) shoot tissue with gibberellic acid (GA₃). Treatment with either auxin or ethephon also decreases the abundance of all three of the GAD RNAs. The tomato ethylene-insensitive mutant, Nr, and the GA-deficient mutant, gib1, were used to show that GA or auxin regulation of GAD RNA abundance is not dependent on ethylene sensitivity, and that ethylene or auxin regulation is not dependent on normal levels of gibberellin biosynthesis. Treatment with abscisic acid (ABA) antagonizes the GA induced suppression of the GAD1 and GAD2 RNAs. GAD1 is similar to type-II wound-inducible plant proteinase inhibitors. Like the well-characterized proteinase inhibitor II (pin II) of tomato, the GAD1 and GAD2 RNAs are wound inducible. Induction of pin II and GAD1 RNA in gib1 was found to require less-severe wounding than was required using wild-type plants or plants doubly mutant for gib1 and sit (the sit mutation causes ABA deficiency). The predicted GAD2 protein sequence is similar to 2-oxoglutarate-dependent dioxygenases while the predicted GAD3 protein sequence is similar to proteins belonging to the nonmetalloshort-chain alcohol-dehydrogenase family, especially the T ASSELSEED2 (TS2) gene of maize and bacterial hydroxysteroid dehydrogenases.