Reduced lignin content and altered lignin composition in the warm season forage grass Paspalum dilatatum by down-regulation of a Cinnamoyl CoA reductase gene.

C4 grasses are favoured as forage crops in warm, humid climates. The use of C4 grasses in pastures is expected to increase because the tropical belt is widening due to global climate change. While the forage quality of Paspalum dilatatum (dallisgrass) is higher than that of other C4 forage grass species, digestibility of warm-season grasses is, in general, poor compared with most temperate grasses. The presence of thick-walled parenchyma bundle-sheath cells around the vascular bundles found in the C4 forage grasses are associated with the deposition of lignin polymers in cell walls. High lignin content correlates negatively with digestibility, which is further reduced by a high ratio of syringyl (S) to guaiacyl (G) lignin subunits. Cinnamoyl-CoA reductase (CCR) catalyses the conversion of cinnamoyl CoA to cinnemaldehyde in the monolignol biosynthetic pathway and is considered to be the first step in the lignin-specific branch of the phenylpropanoid pathway. We have isolated three putative CCR1 cDNAs from P. dilatatum and demonstrated that their spatio-temporal expression pattern correlates with the developmental profile of lignin deposition. Further, transgenic P. dilatatum plants were produced in which a sense-suppression gene cassette, delivered free of vector backbone and integrated separately to the selectable marker, reduced CCR1 transcript levels. This resulted in the reduction of lignin, largely attributable to a decrease in G lignin.

Regions of the Cf-9B disease resistance protein able to cause spontaneous necrosis in Nicotiana benthamiana lie within the region controlling pathogen recognition in tomato.

The tomato Cf-9 and Cf-9B genes both confer resistance to the leaf mold fungus Cladosporium fulvum but only Cf-9 confers seedling resistance and recognizes the avirulence (Avr) protein Avr9 produced by C. fulvum. Using domain swaps, leucine-rich repeats (LRR) 5 to 15 of Cf-9 were shown to be required for Cf-9-specific resistance to C. fulvum in tomato, and the entire N-terminus up to LRR15 of Cf-9B was shown to be required for Cf-9B-specific resistance. Finer domain swaps showed that nine amino-acid differences in LRR 13 to 15 provided sufficient Cf-9-specific residues in a Cf-9B context for recognition of Avr9 in Nicotiana tabacum or sufficient Cf-9B residues in a Cf-9 context for a novel necrotic response caused by the expression of Cf-9B in N. benthamiana. The responses conferred by LRR 13 to 15 were enhanced by addition of LRR 10 to 12, and either region of Cf-9B was found to cause necrosis in N. benthamiana when the other was replaced by Cf-9 sequence in a Cf-9B context. As a consequence, the domain swap with LRR 13 to 15 of Cf-9 in a Cf-9B context gained the dual ability to recognize Avr9 and cause necrosis in N. benthamiana. Intriguingly, two Cf-9B-specific domain swaps gave differing results for necrosis assays in N. benthamiana compared with disease resistance assays in transgenic tomato. The different domain requirements in these two cases suggest that the two assays detect unrelated ligands or detect related ligands in slightly different ways. A heat-sensitive necrosis-inducing factor present in N. benthamiana intercellular washing fluids was found to cause a necrotic response in N. tabacum plants carrying Hcr9-9A, Cf-9B, and Cf-9 but not in plants carrying only Cf-9. We postulate that this necrosis-inducing factor is recognized by Cf-9B either directly as a ligand or indirectly as a regulator of Cf-9B autoactivity.