Phloem-feeding pests cause extensive crop damage throughout the world, yet little is understood about how plants perceive and defend themselves from these threats. The silverleaf whitefly (SLWF; Bemisia tabaci type B) is a good model for studying phloem-feeding insect-plant interactions, as SLWF nymphs cause little wounding and have a long, continuous interaction with the plant. Using the Affymetrix ATH1 GeneChip to monitor the Arabidopsis (Arabidopsis thaliana) transcriptome, 700 transcripts were found to be up-regulated and 556 down-regulated by SLWF nymphs. Closer examination of the regulation of secondary metabolite (glucosinolate) and defense pathway genes after SLWF-instar feeding shows that responses were qualitatively and quantitatively different from chewing insects and aphids. In addition to the RNA profile distinctions, analysis of SLWF performance on wild-type and phytoalexin-deficient4 (pad4) mutants suggests aphid and SLWF interactions with Arabidopsis were distinct. While pad4-1 mutants were more susceptible to aphids, SLWF development on pad4-1 and wild-type plants was similar. Furthermore, although jasmonic acid genes were repressed and salicylic acid-regulated genes were induced after SLWF feeding, cytological staining of SLWF-infested tissue showed that pathogen defenses, such as localized cell death and hydrogen peroxide accumulation, were not observed. Like aphid and fungal pathogens, callose synthase gene RNAs accumulated and callose deposition was observed in SLWF-infested tissue. These results provide a more comprehensive understanding of phloem-feeding insect-plant interactions and distinguish SLWF global responses.
A leucine aminopeptidase (EC 3.4.11.1) cDNA clone (DR57) that was induced in response to Pseudomonas syringae pv. tomato (P.s. tomato) infection was isolated using a subtractive hybridization-enriched cDNA probe. Genomic DNA blot analysis showed that the tomato genome had two leucine aminopeptidase genes. The levels of DR57 mRNAs after P.s. tomato infection and mechanical wounding were determined in two inbred tomato lines that exhibit susceptibility and resistance to P.s. tomato. DR57 mRNAs were detected 12 hours after infection and 4 hours after wounding. Furthermore, DR57 mRNAs were systemically induced in response to wounding. DR57 mRNAs were induced in leaves after Spodoptera littoralis feeding but were not detected in detached leaf controls. Possible roles for the DR57 leucine aminopeptidase in the defense reactions are discussed.In response to pathogen invasion, a large number of plant genes coding for proteins involved in the creation and deposition of physical barriers and development of mechanisms that actively antagonize pathogen growth are induced (for reviews, see refs.
Leucine aminopeptidase A (LapA) is a late wound-response gene of tomato (Solanum lycopersicum). To elucidate the role of LapA, transgenic plants that overexpressed or abolished LapA gene expression were used. The early wound-response gene RNA levels were similar in wild-type and Lap-silenced (LapA-SI), -antisense (LapA-AS), and -overexpressing (LapA-OX) plants. By contrast, late wound-response gene RNA levels and protection against Manduca sexta damage were influenced by LapA RNA and protein levels. While LapA-OX plants had elevated levels of LapA RNAs and protein, ectopic expression of LapA was not sufficient to induce Pin (Ser proteinase inhibitor) or PPO (polyphenol oxidase) transcripts in nonwounded leaves. M. sexta larvae damaged less foliage and displayed delays in growth and development when feeding on LapA-OX plants. By contrast, LapA-SI and LapA-AS lines had lower levels of Pin and PPO RNAs than wild-type controls. Furthermore, larvae consumed more foliage and attained larger masses when feeding on LapA-SI plants. Jasmonic acid (JA) did not complement the wound-signaling phenotype of LapA-SI plants. Based on root elongation in the presence of JA, JA perception appeared to be intact in LapA-SI lines. Collectively, these data suggested that LAP-A has a role in modulating essential defenses against herbivores by promoting late wound responses and acting downstream of JA biosynthesis and perception.
Acad Sci USA 90: [9906][9907][9908][9909][9910]. Polyclonal antibodies to a glutathione S-transferase-LAP fusion protein and affinity-purified antibodies recognizing LAP antigenic determinants detected four classes of polypeptides in tomato (Lycopersicon esculentum) leaves. All four classes had multiple polypeptides in two-dimensional polyacrylamide gel electrophoresis immunoblots. Although antigenically related to the wound-induced tomato LAP proteins, the 77-and 66-kD LAP-like proteins accumulated i n both healthy and wounded leaves. Two classes of 55-kD polypeptides with distinctive isoelectric points were designated as plant LAPs; only the acidic LAP proteins accumulated to high levels after mechanical wounding or Pseodomonas syringae pv tomato infection of tomato leaves. The temporal accumulation of LAP mRNAs was correlated with the increase i n acidic LAP protein subunits. A slow-migrating LAP activity was detected using a native gel assay after wounding. The molecular mass of the native wound-induced LAP enzyme was 353 kD. l h e 55-kD acidic LAP proteins were associated with induced LAP activity, whereas the neutra1 LAPs and the LAP-like proteins were not associated with this exopeptidase. A second, fast-migrating aminopeptidase was detected i n both healthy and wounded tomato leaves. Cell fractionation experiments revealed that wound-induced LAP is a soluble enzyme.Proteins are hydrolyzed to their constituent' amino acids by the sequential action of three types of enzymes: endopeptidases, carboxypeptidases, and aminopeptidases (Callis, 1995). The endopeptidases cleave long polypeptide chains into shorter fragments, which are further degraded at both N and C termini by aminopeptidases and carboxypeptidases, respectively. Aminopeptidases are ubiquitous enzymes, and a wide variety of aminopeptidase activities have been detected in animal, plant, and prokaryotic cells. Aminopeptidase activities have been localized extracellularly (Kenny et al., 1987), within vacuoles (Cueva et al., 1989), in the cytoplasm
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