Wound-induced and developmental activation of a poplar tree chitinase gene promoter in transgenic tobacco

Wounding hybrid poplar (Populus trichocarpa × P. deltoides) trees results in the expression of novel wound-inducible (win) mRNAs thought to encode proteins involved in defense against pests and pathogens. Members of thewin6 gene family encode acidic multi-domain chitinases, with combined structure and charge characteristics that differ from previously described chitinases.Win6 expression has been shown to occur in pooled unwounded leaves of a wounded (on multiple leaves) poplar plant. Here we demonstrate that wounding a single leaf induceswin6 expression locally, in the wounded leaf, and remotely, in specific unwounded leaves with strong vascular connections to the wounded leaf. We also demonstrate that awin6 promoter--glucuronidase (GUS) gene fusion (win6-GUS) responds to wounding locally and remotely in transgenic tobacco. These data indicate that the poplarwin6 promoter has regulatory elements that are responsive to wound signals in the heterologous host. In addition,win6-GUS is developmentally activated in unwounded young leaves and floral tissues of transgenic tobacco. Similar developmental expression patterns are found to occur forwin6 in poplar trees, demonstrating that a herbaceous plant can serve as a host for woody tree transgene analysis and can accurately predict expression patterns in tree tissues (e.g. flowers) that would be difficult to study in free-living trees.     

Chitinase accumulates systemically in wounded poplar trees

Young leaves of poplar ( Populus spp.) trees accumulate novel messenger RNAs shortly after the mature leaves have been mechanically wounded. These systemically wound‐induced ( win ) mRNAs are thought to encode proteins involved in plant defense. In the present paper, transgenic tobacco plants that ectopically expressed a win6 cDNA contained a novel chitinase activity that was not present in normal tobacco. This demonstrated Win6 was a chitinase. Win6 and a related protein Win8 accumulated in wounded poplars. Win6 and Win8 had low isoelectric points (ca 4) as predicted from their nucleotide sequence. The wound‐inducible increase in Win6 and Win8 was correlated with an increase in chitinase (EC 3.2.1.14) activity in poplar leaf extracts. We conclude that mechanical wounding induces chitinase in poplar trees, and speculate that the induced chitinase activity could act to increase the tolerance of poplars to opportunistic wound pathogens.     

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.     

Molecular analysis of herbivore-induced condensed tannin synthesis: cloning and expression of dihydroflavonol reductase from trembling aspen (Populus tremuloides)

In order to study condensed tannin synthesis and its induction by herbivory, a dihydroflavonol reductase (DFR) cDNA was isolated from trembling aspen (Populus tremuloides). Bacterial overexpression demonstrated that this cDNA encodes a functional DFR enzyme, and Southern analysis revealed that DFR likely is a single-copy gene in the aspen genome. Aspen plants that were mechanically wounded showed a dramatic increase in DFR expression after 24 h in both wounded leaves and unwounded leaves on wounded trees. Feeding by forest tent caterpillar (Malacosoma disstria) and satin moth (Leucoma salicis) larvae, and treatment with methyl jasmonate, all strongly induced DFR expression. DFR enzyme activity was also induced in wounded aspen leaves, and phytochemical assays revealed that condensed tannin concentrations significantly increased in wounded and systemic leaves. The expression of other genes involved in the phenylpropanoid pathway were also induced by wounding. Our findings suggest that the induction of condensed tannins, compounds known to be important for defense against herbivores, is mediated by increased expression of DFR and other phenylpropanoid genes.     

Rapid accumulation of trihydroxy oxylipins and resistance to the bean rust pathogen Uromyces fabae following wounding in Vicia faba

BACKGROUND AND AIMS: Insect damage to plants leads to wound-activated responses directed to healing of damaged tissues, as well as activation of defences to prevent further insect damage. Negative cross-talk exists between the jasmonic acid-based signalling system that is activated upon insect attack and the salicylic acid-based system frequently activated following pathogen infection. Thus, insect attack may compromise the ability of the plant to defend itself against pathogens and vice versa. However, insect herbivory and mechanical wounding have been shown to reduce fungal infections on some plants, although the underlying mechanisms remain to be defined. This work examines the effects of mechanical wounding on rust infection both locally and systemically in the broad bean, Vicia faba and follows changes in oxylipins in wounded leaves and unwounded leaves on wounded plants. METHODS: The lamina of first leaves was wounded by crushing with forceps, and first and second leaves were then inoculated, separately, with the rust Uromyces fabae at various times over a 24 h period. Wounded first leaves and unwounded second leaves were harvested at intervals over a 24 h period and used for analysis of oxylipin profiles. KEY RESULTS Mechanical wounding of first leaves of broad bean led to significantly reduced rust infection in the wounded first leaf as well as the unwounded second leaf. Increased resistance to infection was induced in plants inoculated with rust just 1 h after wounding and was accompanied by rapid and significant accumulation of jasmonic acid and two trihydroxy oxylipins in both wounded first leaves and unwounded second leaves. The two trihydroxy oxylipins were found to possess antifungal properties, reducing germination of rust spores. CONCLUSIONS: These results demonstrate the rapidity with which resistance to pathogen infection can be induced following wounding and provides a possible mechanism by which pathogen infection might be halted.     

Nucleotide sequence and regulated expression of a wound-inducible potato gene (wun1)

Summary Mechanical wounding of potato leaves, stems, roots and tubers leads to a rapid increase of wun1 mRNA. In potato leaves, the wound-induced accumulation of wun1 mRNA is inhibited by the addition of sucrose or other osmotically active agents. This inhibition is organ specific since sucrose does not prevent wun1 mRNA accumulation in wounded tubers. In contrast, expression of patatin was shown to be repressed in tubers by wounding and this repression was reversed by increasing osmotic pressure. Sequence data obtained from the analysis of a wun1 cDNA and a wun1 genomic clone show no homology to any gene known so far. Histochemical data demonstrate a striking analogy in cell specific expression of chimeric genes expressed under the control of the wun1 promoter and the cell specific production of callose in wounded tobacco leaves.     

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.     

Partial purification of proteinase inhibitors from wounded tomato plants

Proteinase inhibitors were extracted from the upper leaves of tomato plants, Lycopersicon esculentum Mill., 48 hours after wounding single lower leaves. Inhibitors were partially purified by affinity chromatography and isoelectric focusing. Significantly higher levels of trypsin and chymotrypsin inhibitory activity were recovered from wounded plants than from unwounded controls. Several inhibitor peaks were partially resolved by isoelectric focusing of affinity column eluates from both wounded and control plants. Inhibitor activity associated with each peak was greater in wounded plants than in corresponding peaks of controls. Agar double diffusion immunological assays showed that inhibitors with basic isoelectric points (pI) of 9.5, 8.9, 8.3, 8.2, and 8.0 are serologically related to inhibitor I. Certain of these inhibitors (pI = 9.5, 8.2, and 8.0) reacted strongly with both inhibitors I and II antiserum. Three acidic proteinase inhibitors (pI = 6.5, 5.9, and 4.7), which accumulated due to wounding, also were isolated. These inhibitors are novel, since they were shown to be serologically unrelated to inhibitors I and II.     

Accumulation of a metallo-carboxypeptidase inhibitor in leaves of wounded potato plants

Mechanical wounding of young potato plants induces over a two fold increase in inhibitory activity against the bovine pancreatic metalloexopeptidase carboxypeptidase A. This increase in inhibitory activity in both wounded and unwounded leaves parallels the increases of two inhibitors of bovine serine endopeptidases, trypsin and chymotrypsin. This suggests that the Proteinase Inhibitor Inducing Factor is regulating the synthesis and accumulation of inhibitors of two different mechanistic classes of proteases found in animals and microorganisms. These increases in antiproteolytic activities due to wounding support the hypothesis that this response is part of a defense mechanism directed against plant pests.     

Effect of Ethylene Action Inhibitors upon Wound-Induced Gene Expression in Tomato Pericarp

The contribution of wound-ethylene to wound-induced gene expression was investigated in unripe tomato pericarp using inhibitors of ethylene action. Wounded unripe tomato pericarp was treated with 2,5-norbornadiene or silver thiosulfate to inhibit specifically the induction of ethylene-dependent mRNA species. Poly(A)⁺ RNAs isolated from these tissues after 12 hours of wounding were translated in vitro in a rabbit reticulocyte lysate system and [³⁵S]methionine-labeled polypeptides were compared to unwounded controls after separation by one and two-dimensional polyacrylamide gel electrophoresis. Results show that mechanical wounding induces a dramatic shift in gene expression (over 50 mRNA species) but expression of less than 15% of these genes is affected by the treatment with ethylene action inhibitors. A selective decrease in mRNAs coding for a 37 kilodalton doublet and 75 kilodalton polypeptides is observed in 2,5-norbornadiene and silver thiosulfate treated wounded pericarp. Levels of hydroxyproline-rich glycoprotein mRNAs induced in wounded tissue were not influenced by inhibitors of ethylene action.     

Fast upward propagation of the wound signal that systemically elevates phosphatidic acid

Phosphatidic acid (PA) increases in response to wounding at the neighboring unwounded leaf as well as at the wounded leaf of many plants (Lee et al., 1997). This indicates that a signal propagates from the wounded leaf to its neighboring leaves. In this paper, we report the speed and direction of propagation for a systemic wound signal that elevates PA. When a leaf of a soybean (Glycine max) seedling at the 2-leaf-stage was wounded, the PA level of the neighboring leaf did not change within the first min, but did increase significantly in 2 min, returning to the control level after 15 min. This implies that the systemic wound signal was generated at least within 2 min of wounding, and was propagated at a speed of at least 10–16 mm/min. When we wounded individual leaves of soybean and tobacco (Nicotiana tabaccum) seedlings that had 3 or 4 leaves, PA levels were elevated only in the younger leaves located above the wounded leaf, but not in the older, lower leaves. Thus, the PA-elevating wound signal preferentially moves upward in these plants.