G. Salvi

The crystal structure of polygalacturonase-inhibiting protein (PGIP), a leucine-rich repeat protein involved in plant defense.

Polygalacturonase-inhibiting proteins (PGIPs) are plant cell wall proteins that protect plants from fungal invasion. They interact with endopolygalacturonases secreted by phytopathogenic fungi, inhibit their enzymatic activity, and favor the accumulation of oligogalacturonides, which activate plant defense responses. PGIPs are members of the leucine-rich repeat (LRR) protein family that in plants play crucial roles in development, defense against pathogens, and recognition of beneficial microbes. Here we report the crystal structure at 1.7-Å resolution of a PGIP from Phaseolus vulgaris. The structure is characterized by the presence of two β-sheets instead of the single one originally predicted by modeling studies. The structure also reveals a negatively charged surface on the LRR concave face, likely involved in binding polygalacturonases. The structural information on PGIP provides a basis for designing more efficient inhibitors for plant protection.

Polygalacturonase-inhibiting proteins (PGIPs) with different specificities are expressed in Phaseolus vulgaris

The pgip-1 gene of Phaseolus vulgaris, encoding a polygalacturonase-inhibiting protein (PGIP), PGIP-1 (P. Toubart, A. Desiderio, G. Salvi, F. Cervone, L. Daroda, G. De Lorenzo, C. Bergmann, A. G. Darvill, and P. Albersheim, Plant J. 2:367-373, 1992), was expressed under control of the cauliflower mosaic virus 35S promoter in tomato plants via Agrobacterium tumefaciens-mediated transformation. Transgenic tomato plants with different expression levels of PGIP-1 were used in infection experiments with the pathogenic fungi Fusarium oxysporum f. sp. lycopersici, Botrytis cinerea, and Alternaria solani. No evident enhanced resistance, compared with the resistance of untransformed plants, was observed. The pgip-1 gene was also transiently expressed in Nicotiana benthamiana with potato virus X (PVX) as a vector. PGIP-1 purified from transgenic tomatoes and PGIP-1 in crude protein extracts of PVX-infected N. benthamiana plants were tested with several fungal polygalacturonases (PGs). PGIP-1 from both plant sources exhibited a specificity different from that of PGIP purified from P. vulgaris (bulk bean PGIP). Notably, PGIP-1 was unable to interact with a homogeneous PG from Fusarium moniliforme, as determined by surface plasmon resonance analysis, while the bulk bean PGIP interacted with and inhibited this enzyme. Moreover, PGIP-1 expressed in tomato and N. benthamiana had only a limited capacity to inhibit crude PG preparations from F. oxysporum f. sp. lycopersici, B. cinerea, and A. solani. Differential affinity chromatography was used to separate PGIP proteins present in P. vulgaris extracts. A PGIP-A with specificity similar to that of PGIP-1 was separated from a PGIP-B able to interact with both Aspergillus niger and F. moniliforme PGs. Our data show that PGIPs with different specificities are expressed in P. vulgaris and that the high-level expression of one member (pgip-1) of the PGIP gene family in transgenic plants is not sufficient to confer general, enhanced resistance to fungi.

Pectin methylesterase is induced in Arabidopsis upon infection and is necessary for a successful colonization by necrotrophic pathogens.

The ability of bacterial or fungal necrotrophs to produce enzymes capable of degrading pectin is often related to a successful initiation of the infective process. Pectin is synthesized in a highly methylesterified form and is subsequently de-esterified in muro by pectin methylesterase. De-esterification makes pectin more susceptible to the degradation by pectic enzymes such as endopolygalacturonases (endoPG) and pectate lyases secreted by necrotrophic pathogens during the first stages of infection. We show that, upon infection, Pectobacterium carotovorum and Botrytis cinerea induce in Arabidopsis a rapid expression of AtPME3 that acts as a susceptibility factor and is required for the initial colonization of the host tissue.

Oligogalacturonides Prevent Rhizogenesis in rolB-Transformed Tobacco Explants by Inhibiting Auxin-Induced Expression of the rolB Gene.

Oligogalacturonides elicit several defense responses and regulate different aspects of growth and development in plants. Many of the development-related effects of oligogalacturonides appear to be amenable to an auxin antagonist activity of these oligosaccharins. To clarify the role of oligogalacturonides in antagonizing auxin, we analyzed their effect on root formation in leaf explants of tobacco harboring the plant oncogene rolB. We show here that oligogalacturonides are capable of inhibiting root morphogenesis driven by rolB in transgenic leaf explants when this process requires exogenous auxin. Because rolB expression is induced by auxin and dramatically alters the response to this hormone in transformed plant cells, the inhibiting effect of oligogalacturonides could be exerted on the induction of rolB and/or at some other auxin-requiring step(s) in rhizogenesis. We show that oligogalacturonides antagonize auxin primarily because they strongly inhibit auxin-regulated transcriptional activation of a rolB-[beta]-glucuronidase gene fusion in both leaf explants and cultured leaf protoplasts. In contrast, oligogalacturonides do not inhibit rhizogenesis when rolB transcriptional activation is made independent of auxin, as shown by the lack of inhibition of root formation in leaf explants containing rolB driven by a tetracycline-inducible promoter.

Mutagenesis of endopolygalacturonase from Fusarium moniliforme: histidine residue 234 is critical for enzymatic and macerating activities and not for binding to polygalacturonase-inhibiting protein (PGIP).

The sequence encoding the endopolygalacturonase (PG) of Fusarium moniliforme was cloned into the E. coli/yeast shuttle vector Yepsec1 for secretion in yeast. The recombinant plasmid (pCC6) was used to transform Saccharomyces cerevisiae strain S150-2B; transformed yeast cells were able to secrete PG activity into the culture medium. The enzyme (wtY-PG) was purified, characterized, and shown to possess biochemical properties similar to those of the PG purified from F. moniliforme. The wtY-PG was able to macerate potato medullary tissue disks and was inhibited by the polygalacturonase-inhibiting protein (PGIP) purified from Phaseolus vulgaris. The sequence encoding PG in pCC6 was subjected to site-directed mutagenesis. Three residues in a region highly conserved in all the sequences known to encode PGs were separately mutated: His 234 was mutated into Lys (H 234-->K), and Ser 237 and Ser 240 into Gly (S 237-->G and S 240-->G). Each of the mutated sequences was used to transform S. cerevisiae and the mutated enzymes were purified and characterized. Replacement of His 234 with Lys abolished the enzymatic activity, confirming the biochemical evidence that a His residue is critical for enzyme activity. Replacement of either Ser 237 or Ser 240 with Gly reduced the enzymatic activity to 48% and 6%, respectively, of the wtY-PG. When applied to potato medullary tissue, F. moniliforme PG and wtY-PG caused comparable maceration, while the variant PGs exhibited a limited (S 234-->G and S 240-->G) or null (H 234-->K) macerating activity. The interaction between the variant enzymes and the P. vulgaris PGIP was investigated using a biosensor based on surface plasmon resonance (BIAlite). The three variant enzymes were still able to interact and bind to PGIP with association constants comparable to that of the wild type enzyme.

A Polygalacturonase-Inhibiting Protein in the Flowers of Phaseolus vulgaris L.

Summary The localization of the endopolygalacturonase inhibiting protein (PGIP) has been studied in Phaseolus vulgaris L. by a simple infiltration-extraction procedure. Virtually all of the PGIP activity was recovered from the bean stem apoplast without significantly disturbing the symplastic component of the tissue. Activity of PGIP was determined in different parts and organs of developing bean seedlings. PGIP was present in all the tissues and organs tested (root, leaf, cotyledon, flower, stem, seed, embryo). Very low levels of PGIP were found in the roots. Higher specific activities were detected in all the other parts of the plant, the highest PGIP levels being detected in the vegetative apex and in the flower. PGIP levels in the stems increased during plant growth. At different stages of development a differential expression of PGIP along the stem was observed and an acropetal shift of the zone of maximum PGIP expression occurred. PGIP from Phaseolus vulgaris flowers was purified 32-fold by DEAE-cellulose chromatography followed by affinity chromatography through a Sepharose-endopolygalacturonase column. The purified PGIP, subjected to SDS-PAGE, showed a mobility similar but not identical to that of PGIP purified from hypocotyls. A molecular mass of 42 kDa was calculated for the flower PGIP, 1kDa larger than the molecular mass of the PGIP purified from stems.

Cytological localization of thePGIP genes in the embryo suspensor cells ofPhaseolus vulgavis L

Polygalacturonase-inhibiting protein (PGIP) is a cell wall protein which inhibits fungalendopolygalacturonases. A small gene family encodesPGIP in the genome of common bean, as indicated by Southernblot experiments performed at high-stringency conditions. Southern-blot analysis of DNA extracted from different cultivars ofPhaseolus vulgaris and fromPhaseolus coccineus showed length polymorphism of the hybridizing restriction fragments. The cytological localization of thePGIP genes was determined in polytene chromosomes of theP. vulgaris embryo suspensor cells. In-situ hybridization experiments using the clonedPGIP gene revealed labelling over a single region of the pericentromeric heterochromatin of chromosome pair X, next to the euchromatin, suggesting thatPGIP gene family may be clustered in one chromosomal region.

Induction of Extracellular Polygalacturonase and Its mRNA in the Phytopathogenic Fungus Fusarium moniliforme

SUMMARY: The activity of extracellular polygalacturonase (PG) was strongly induced in Fusarium moniliforme by growing the fungus in a minimal medium containing pectin as sole carbon source. PG was the major protein component of the extracellular fluid whereas no detectable PG activity was found in culture filtrates of the fungus grown in a medium containing glucose as carbon source. F. moniliforme PG was purified to homogeneity by a procedure involving ammonium sulphate precipitation, carboxymethyl cellulose chromatography and preparative isoelectric focusing. The purified protein showed one protein band in non-denaturating PAGE and two major bands (molecular mass 41.5 and 45.kDa) plus two minor bands (38.0 and 48.5 kDa) in SDS-PAGE. The bands consisted of glycosylated polypeptide chains. Poly(A)-containing RNA, purified from total RNA extracted from F. moniliforme grown in PG-inducing conditions and translated in vitro in a reticulocyte cell-free translation system, produced two polypeptide chains (47 and 51 kDa) which were not present in the translation products of the non-induced poly(A)-containing RNA. The two polypeptide chains were immunoprecipitated with an IgG against F. moniliforme homogeneous PG.

Molecular evolution of fungal polygalacturonase

In plant-fungi interactions the establishment of basic compatibility occurs when a potential pathogen acquires functions that allow colonization of host plant species and/or suppression or neutralization of host resistance responses. Cultivar and race-specific resistance (specific compatibility) is generally considered as superimposed in host-parasite systems which have already acquired basic compatibility. Specific compatibility is achieved with the matching of two molecules which are products of one gene in the host and one gene in the parasite [1,2]. However a plausible and economical evolutionary strategy could utilize, for specific compatibility, the same molecules involved in basic compatibility, if their structure and function are flexible enough.

Oligogalacturonides stimulate pericycle cell wall thickening and cell divisions leading to stoma formation in tobacco leaf explants

Abstract. Novel developmental events induced by micromolar concentrations of oligogalacturonides (OGs) in tobacco leaf explants cultured in vitro are described. Oligogalacturonides induced acceleration and synchronization of the mitotic activity of guard-cell precursors in the epidermis. In explants cultured for 24 h in the presence of OGs, the number of stomatal mitoses was higher than that observed in explants cultured in the absence of OGs; however, at the end of the culture period the density of mature stomata did not vary upon OG treatment. The OG-induced activation of stomatal mitosis was reduced by exogenously added indole-3-acetic acid (IAA). Oligogalacturonides also enhanced mean wall thickness, mainly due to cellulose deposition, of foliar pericycle cells, as well as the number of extra-thick-walled pericycle cells; the pericycle thus formed a sheath surrounding phloem and xylem. Indole-3-acetic acid decreased the number of extra-thick-walled cells forming in the presence of OGs but did not influence wall thickness. Moreover, OGs inhibited the stimulation of mitotic activity of phloem parenchyma cells (vascular mitoses) induced by auxin, leading to a nearly complete inhibition of IAA-induced formation of callus and of meristemoids of indirect origin. Instead, OGs did not influence mitotic activity occurring in the absence of auxin. All in all, our results provide further evidence of the pleiotropic role exerted on plant development by these oligosaccharins, and of the antagonism between auxin and OGs.