David P. Puthoff

Expression of an Arabidopsis phosphoglycerate mutase homologue is localized to apical meristems, regulated by hormones, and induced by sedentary plant-parasitic nematodes

We previously isolated a partial soybean cDNA clone whose transcript abundance is increased upon infection by the sedentary, endoparasitic soybean cyst nematode Heterodera glycines. We now isolated the corresponding full-length cDNA and determined that the predicted gene product was similar to the group of cofactor-dependent phosphoglycerate mutase/bisphosphoglycerate mutase enzymes (PGM/bPGM; EC 5.4.2.1/5.4.2.4). We designated the corresponding soybean gene GmPGM. PGM and bPGM are key catalysts of glycolysis that have been well characterized in animals but not plants. Using the GmPGM cDNA sequence, we identified a homologous Arabidopsis thaliana gene, which we designatedAtPGM. Histochemical GUS analyses of transgenic Arabidopsis plants containing theAtPGM promoter::GUS construct revealed that the AtPGM promoter directs GUS expression in uninfected plants only to the shoot and root apical meristems. In infected plants, GUS staining also is evident in the nematode feeding structures induced by the cyst nematode Heterodera schachtii and by the root-knot nematode Meloidogyne incognita. Furthermore, we discovered that the AtPGM promoter was down-regulated by abscisic acid and hydroxyurea, whereas it was induced by sucrose, oryzalin, and auxin, thereby revealing expression characteristics typical of genes with roles in meristematic cells. Assessment of the auxin-inducible AUX1 gene promoter (a gene coding for a polar auxin transport protein) similarly revealed feeding cell and meristem expression, suggesting that auxin may be responsible for the observed tissue specificity of the AtPGM promoter. These results provide first insight into the possible roles of PGM/bPGM in plant physiology and in plant-pathogen interactions.

A novel wheat gene encoding a putative chitin-binding lectin is associated with resistance against Hessian fly.

SUMMARY The gene-for-gene interaction triggering resistance of wheat against first-instar Hessian fly larvae utilizes specialized defence response genes not previously identified in other interactions with pests or pathogens. We characterized the expression of Hfr-3, a novel gene encoding a lectin-like protein with 68-70% identity to the wheat germ agglutinins. Within each of the four predicted chitin-binding hevein domains, the HFR-3 translated protein sequence contained five conserved saccharide-binding amino acids. Quantification of Hfr-3 mRNA levels confirmed a rapid response and gradual increase, up to 3000-fold above the uninfested control in the incompatible interaction 3 days after egg hatch. Hfr-3 mRNA abundance was influenced by the number of larvae per plant, suggesting that resistance is localized rather than systemic. In addition, Hfr-3 was responsive to another sucking insect, the bird cherry-oat aphid, but not to fall armyworm attack, wounding or exogenous application of methyl jasmonate, salicylic acid or abscisic acid. Western blot analysis demonstrated that HFR-3 protein increased in parallel to mRNA levels in crown tissues during incompatible interactions. HFR-3 protein was detected in both virulent and avirulent larvae, indicating ingestion. Anti-nutritional proteins, such as lectins, may be responsible for the apparent starvation of avirulent first-instar Hessian fly larvae during the initial few days of incompatible interactions with resistant wheat plants.

Hfr‐2, a wheat cytolytic toxin‐like gene, is up‐regulated by virulent Hessian fly larval feeding‡

SUMMARY Both yield and grain-quality are dramatically decreased when susceptible wheat (Triticum aestivum) plants are infested by Hessian fly (Mayetiola destructor) larvae. Examination of the changes in wheat gene expression during infestation by virulent Hessian fly larvae has identified the up-regulation of a gene, Hessian fly responsive-2 (Hfr-2), which contains regions similar to genes encoding seed-specific agglutinin proteins from Amaranthus. Hfr-2, however, did not accumulate in developing seeds, as do other wheat seed storage proteins. Additionally, a separate region of the HFR-2 predicted amino acid sequence is similar to haemolytic proteins, from both mushroom and bacteria, that are able to form pores in cell membranes of mammalian red blood cells. The involvement of Hfr-2 in interactions with insects was supported by experiments demonstrating its up-regulation by both fall armyworm (Spodoptera frugiperda) and bird cherry-oat aphid (Rhopalosiphum padi) infestations but not by virus infection. Examination of wheat defence response pathways showed Hfr-2 up-regulation following methyl jasmonate treatment and only slight up-regulation in response to salicylic acid, abscisic acid and wounding treatments. Like related proteins, HFR-2 may normally function in defence against certain insects or pathogens. However, we propose that as virulent Hessian fly larvae manipulate the physiology of the susceptible host, the HFR-2 protein inserts in plant cell membranes at the feeding sites and by forming pores provides water, ions and other small nutritive molecules to the developing larvae.

GmEREBP1 Is a Transcription Factor Activating Defense Genes in Soybean and Arabidopsis

Ethylene-responsive element-binding proteins (EREBPs) are plant-specific transcription factors, many of which have been linked to plant defense responses. Conserved EREBP domains bind to the GCC box, a promoter element found in pathogenesis-related (PR) genes. We previously identified an EREBP gene from soybean (GmEREBP1) whose transcript abundance decreased in soybean cyst-nematode-infected roots of a susceptible cultivar, whereas it increased in abundance in infected roots of a resistant cultivar. Here, we report further characterization of this gene. Transient expression analyses showed that GmEREBP1 is localized to the plant nucleus and functions as a transcriptional activator in soybean leaves. Transgenic soybean plants expressing GmEREBP1 activated the expression of the ethylene (ET)-responsive gene PR2 and the ET- and jasmonic acid (JA)-responsive gene PR3, and the salicylic acid (SA)-responsive gene PR1 but not the SA-responsive PR5. Similarly, transgenic Arabidopsis plants expressing GmEREBP1 showed elevated mRNA abundance of the ET-regulated gene PR3 and the ET- and JA-regulated defense-related gene PDF1.2 but not the ET-regulated GST2, and the SA-regulated gene PR1 but not the SA-regulated PR2 and PR5. Transgenic soybean and Arabidopsis plants inoculated with cyst nematodes did not display a significantly altered susceptibility to nematode infection. These results collectively show that GmEREBP1 functions as a transacting inducer of defense gene expression in both soybean and Arabidopsis and mediates the expression of both ET- and JA- and SA-regulated defense-related genes in these plant species.

Insect feeding-induced differential expression of Beta vulgaris root genes and their regulation by defense-associated signals

Root responses to insect pests are an area of plant defense research that lacks much information. We have identified more than 150 sugar beet root ESTs enriched for genes responding to sugar beet root maggot feeding from both moderately resistant, F1016, and susceptible, F1010, genotypes using suppressive subtractive hybridization. The largest number of identified F1016 genes grouped into the defense/stress response (28%) and secondary metabolism (10%) categories with a polyphenol oxidase gene, from F1016, identified most often from the subtractive libraries. The differential expression of the root ESTs was confirmed with RT-PCR. The ESTs were further characterized using macroarray-generated expression profiles from F1016 sugar beet roots following mechanical wounding and treatment of roots with the signaling molecules methyl jasmonate, salicylic acid and ethylene. Of the examined root ESTs, 20, 17 and 11% were regulated by methyl jasmonate, salicylic acid and ethylene, respectively, suggesting these signaling pathways are involved in sugar beet root defense responses to insects. Identification of these sugar beet root ESTs provides knowledge in the field of plant root defense and will lead to the development of novel control strategies for control of the sugar beet root maggot.

Homologous soybean and Arabidopsis genes share responsiveness to cyst nematode infection

SUMMARY We previously isolated a partial soybean cDNA clone (D17.1) whose corresponding transcript increases in susceptible roots 1 day post inoculation (dpi) with the soybean cyst nematode, Heterodera glycines. Here we isolated the corresponding full-length cDNA from a soybean cDNA library and designated this gene of unknown function Gm17.1. Time course RNA gel blot analyses revealed that Gm17.1 mRNA steady-state levels were elevated in soybean roots following H. glycines infection up to at least 6 dpi. For further in-depth study we identified a homologous Arabidopsis thaliana gene and designated this gene At17.1. Arabidopsis is successfully infected by the sugar beet cyst nematode (H. schachtii), a close relative of H. glycines. We isolated the At17.1 promoter, fused it to the beta-glucuronidase (GUS) reporter gene, and transformed this construct into Arabidopsis plants as well as soybean hairy roots. Histochemical analysis of plant materials containing the At17.1::GUS construct revealed that the At17.1 promoter is functional in Arabidopsis as well as in soybean and that during normal plant development the At17.1 promoter directs GUS expression predominantly to the vascular tissues and root tips of both plant species. When At17.1::GUS Arabidopsis plants and soybean hairy roots were inoculated with cyst nematodes, strong GUS activity was detected within the cyst nematode-induced feeding structures. Further tests of At17.1 promoter activity in Arabidopsis revealed that this promoter was induced by auxin, jasmonic acid, mannitol and dehydration. Quantitative real-time reverse transcription-polymerase chain reaction assays of At17.1 expression confirmed the observed promoter characteristics. Based on our expression data and the observation that both the soybean and the Arabidopsis homologues behaved in a similar fashion following cyst nematode infection, it is likely that these genes are closely associated with cyst nematode parasitism of plants, potentially with hormone and osmotic changes occurring in the developing nematode feeding cells. Furthermore, these data provide additional insights into the strengths of the Arabidopsis-H. schachtii pathosystem to study cyst nematode-plant interactions in lieu of less tractable pathosystems. This finding is supported by the fact that the Arabidopsis promoter tested here produced similar results in Arabidopsis and soybean.

ATP-dependent Hexameric Assembly of the Heat Shock Protein Hsp101 Involves Multiple Interaction Domains and a Functional C-proximal Nucleotide-binding Domain

Members of the Hsp100 family of heat stress proteins are present in species throughout the bacterial, plant, and fungal kingdoms. Most Hsp100 proteins are composed of five domains that include two nucleotide-binding domains required for their ATP-dependent oligomerization. Mutations within the first but not the second nucleotide-binding site disrupt self-assembly of bacterial Hsp100, whereas the reverse is true for yeast Hsp104. We have examined the functional requirements for oligomerization of plant Hsp101 and have found that Hsp101 resembles Hsp104 in that it assembles into a hexameric complex in an ATP-dependent manner. Self-assembly of Hsp101 involves at least three distinct interaction domains located in the N-proximal domain and in the first and second nucleotide-binding domains. The interaction domain in the second nucleotide-binding domain included the Walker A motif, and mutations within this element disrupted self-assembly of Hsp101. In contrast, mutations affecting conserved residues of the Walker A motif within the first nucleotide-binding site did not affect self-assembly. No interaction between Hsp101 and Hsp104 was observed. These results suggest that plant Hsp101 self-assembly involves multiple evolutionarily diverged interaction domains as well as an evolutionarily conserved requirement for a functional C-proximal nucleotide-binding site.

Recent advances in functional genomics for sugar beet (Beta vulgaris L.) improvement: progress in determining the role of BvSTI in pest resistance in roots

To gain knowledge of root resistance mechanisms in sugar beet, Beta vulgaris L., our laboratory has been studying the interaction of sugar beet with its most devastating insect pest, the sugar beet root maggot (SBRM; Tetanops myopaeformis Roder). Damage from SBRM infestations is a serious problem and current control measures rely on environmentally damaging insecticides. We recently reported root-specific gene expression incited by SBRM feeding in a moderately resistant F1016 and a susceptible parental F1010 line. AcDNA expressed sequence tag (EST) coding for a serine (trypsin-type) protease inhibitor (BvSTI) was identified and investigated further here. BvSTI shares sequence similarity with a root-specific tomato gene whose expression is induced by insect feeding. Since serine proteases comprise the major digestive enzymes in root maggot midguts, we hypothesize BvSTI may be involved in resistance. To elucidate the functional role of BvSTI, its coding region was fused to the CaMV 35S promoter and constitutively expressed in sugar beet hairy roots and N. benthamiana plants. In BvSTI-transformed F1010 hairy roots, trypsin inhibitory activity increased 2 to 4-fold. Using a polyacrylamide gel assay, new trypsin-like PI activity was detected in BvSTI-N. benthamiana plants. Since SBRM cannot be reared in vitro, two other insects that utilize serine digestive proteases, fall armyworm (Spodoptera frugiperda) and tobacco hornworm (Manduca sexta), were screened for resistance. To date, we demonstrated that 1) fall armyworm will feed on sugar beet hairy roots and 2) tobacco hornworm fed BvSTI-N. benthamiana leaves had reduced weights and pupal sizes. These results suggest that BvSTI may contribute to the moderate resistance of F1016 roots to SBRM. Functional analysis of additional ESTs will further support efforts to characterize the components of sugar beet root resistance mechanisms.