Martha L. Orozco-Cárdenas

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 (H2O2) 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 H2O2-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. H2O2 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 H2O2 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 H2O2 signals for systemic signaling in tomato plants 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 andS-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 (H2O2) production and proteinase inhibitor synthesis that was induced by systemin, oligouronides, and jasmonic acid (JA). However, H2O2 generated by glucose oxidase and glucose was not blocked by NO, nor was H2O2-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 H2O2 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 H2O2synthesis. The results suggest that NO may have a role in down-regulating the expression of wound-inducible defense genes during pathogenesis.

Autoradiographic and biochemical evidence for the systemic translocation of systemin in tomato plants

The movement of systemin, the 18-amino-acid polypeptide inducer of proteinase inhibitors in tomato (Lycopersicon esculentum L.) plants, was investigated in young tomato plants following the application of [14C]systemin to wounds on the surface of leaves. Wholeleaf autoradiographic analyses revealed that [14C]systemin was distributed throughout the wounded leaf within 30 min, and then during the next several hours was transported to the petiole, to the main stem, and to the upper leaves. The movement of [14C]systemin was similar to the movement of [14C]sucrose when applied to leaf wounds, except that sucrose was slightly more mobile than systemin. Analyses of the radioactivity in the petiole phloem exudates at intervals over a 5-h period following the application of [14C]systemin to a wound demonstrated that intact [14C]systemin was present in the phloem over the entire time, indicating that the polypeptide was either stable for long periods in the phloem or was being continually loaded into the phloem from the source leaf. The translocation pathway of systemin was also investigated at the cellular level, using light microscopy and autoradiography. Within 15 min after application of [3H]systemin to a wound on a terminal leaflet, it was found distributed throughout the wounded leaf and was primarily concentrated in the xylem and phloem tissues within the leaf veins. After 30 min, the radioactivity was found mainly associated with vascular strands of phloem tissue in the petiole and, at 90 min, label was found in the phloem of the main stem. Altogether, these and previous results support a role for systemin as a systemic wound signal in tomato plants.

Advancing Crop Transformation in the Era of Genome Editing

Plant transformation has enabled fundamental insights into plant biology and revolutionized commercial agriculture. Unfortunately, for most crops, transformation and regeneration remain arduous even after more than 30 years of technological advances. Genome editing provides novel opportunities to enhance crop productivity but relies on genetic transformation and plant regeneration, which are bottlenecks in the process. Here, we review the state of plant transformation and point to innovations needed to enable genome editing in crops. Plant tissue culture methods need optimization and simplification for efficiency and minimization of time in culture. Currently, specialized facilities exist for crop transformation. Single-cell and robotic techniques should be developed for high-throughput genomic screens. Plant genes involved in developmental reprogramming, wound response, and/or homologous recombination should be used to boost the recovery of transformed plants. Engineering universal Agrobacterium tumefaciens strains and recruiting other microbes, such as Ensifer or Rhizobium, could facilitate delivery of DNA and proteins into plant cells. Synthetic biology should be employed for de novo design of transformation systems. Genome editing is a potential game-changer in crop genetics when plant transformation systems are optimized.

Differential expression of a chimeric CaMV-tomato proteinase Inhibitor I gene in leaves of transformed nightshade, tobacco and alfalfa plants.

The open reading frame and terminator region of a wound-inducible tomato Inhibitor I gene, regulated by the CaMV 35S promoter, was stably integrated into the genomes of nightshade (Solanum nigrum), tobacco (Nicotiana tabacum), and alfalfa (Medicago sativa), using an Agrobacterium-mediated transformation system. The expression of the foreign Inhibitor I gene in leaves of each species was studied at the mRNA and protein levels. The levels of Inhibitor I protein present in leaves of each species correlated with the levels of mRNA. The average levels of both mRNA and Inhibitor I protein were highest in leaves of transgenic nightshade plants (over 125 μg of Inhibitor I per g tissue), less in tobacco plants (about 75 μg/g tissue), and lowest in leaves of transgenic alfalfa plants (below 20 μg/g tissue). Inhibitor I protein was observed in all tissues throughout transgenic plant species, but inhibitor concentration per gram of tissue was 2–3 times higher in young developing leaf tissues and floral organs. The differences in the expression of the CaMV-tomato Inhibitor I gene among the different plant genera suggests that either the rate of transcription of the foreign gene or the rate of degradation of the nascent Inhibitor I mRNA varies among genera. Using electron microscopy techniques, the newly synthesized pre-pro-Inhibitor I protein was shown to be correctly processed and stored as a mature Inhibitor I protein within the central vacuoles of leaves of transgenic nightshade and alfalfa. The results of these experiments suggest that maximal expression of foreign proteinase inhibitor genes, and perhaps other foreign defense genes, may require gene constructs that are fashioned with promoters and terminators that allow maximum expression in the selected plant species.

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.

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.

Polygalacturonase β-Subunit Antisense Gene Expression in Tomato Plants Leads to a Progressive Enhanced Wound Response and Necrosis in Leaves and Abscission of Developing Flowers

Tomato (Lycopersicon esculentum var. Better Boy) plants were transformed with a tomato leaf wound-inducible polygalacturonase (PG) β-subunit gene in the antisense orientation (PGβS-AS) under the control of the cauliflower mosaic virus 35S promoter. The leaves of the transgenic plants exhibited small localized lesions, which eventually enlarged and spread throughout the entire surfaces of the leaves, resulting in cell death. The same lesions were also observed in the peduncle of developing flowers, extending to the whole flower causing abscission, resulting in a sterile phenotype. Leaves of transgenic plants exhibited elevated levels of PG activity, hydrogen peroxide, and enhanced defense signaling in response to wounding and elicitor treatment. The defense signaling increased was accompanied by an increased resistance toward tobacco hornworm (Manduca sexta) larvae. The cumulative results suggest that in the absence of the β-subunit protein in tomato leaves, an increase in PG activity occurred that led to an enhanced wound response, the formation of lesions leading to severe necrosis, and an abscission of developing flowers.

Systemins and AtPeps: Defense-Related Peptide Signals

Plants have evolved different families of functionally related peptide signals (15–23 amino acids) that serve to amplify the defense response against insect/herbivore and pathogen attacks through the activation of the octadecanoid signaling pathway. The peptides are derived from larger precursor proteins and released into the extracellular space to interact with membrane receptors by still unknown processing mechanisms. Besides scarce sequence similarities among defense-related peptide signals, their functional properties still suggest some common ancestral origin for defense peptide signaling systems in plants and animals.

Tomato ( Solanum lycopersicum )

Agrobacterium-mediated transformation is the most common method for the incorporation of foreign genes into the genome of tomato as well as many other species in the Solanaceae family. This chapter describes a protocol for the genetic transformation of tomato cultivar Micro-Tom using cotyledons as explants. Detailed procedures are also included for determining gene-copy number using a duplex qPCR TaqMan assay, and the histochemical analysis of GUS expression.