Phosphatidic acid accumulation is an early response in the Cf-4/Avr4 interaction.

The Cladosporium fulvum (Cf)-4 gene of tomato confers resistance to the fungus C. fulvum, expressing the corresponding avirulence (Avr)4 gene, which codes for an elicitor protein. Little is known about how such mechanisms work, but previous studies have shown that elicitor recognition activates Ca(2+) signalling and protein kinases, such as mitogen-activated protein kinase (MAPK) and calcium-dependent protein kinase (CDPK). Here, we provide evidence that a new signalling component, the lipid second messenger phosphatidic acid (PA), is produced within a few minutes of AVR4/Cf-4 interaction. Using transgenic tobacco cells expressing the tomato Cf-4-resistance gene as a model system, phospholipid signalling pathways were studied by pre-labelling the cells with (32)P(i) and assaying for the formation of lipid signals after challenge with the fungal elicitor AVR4. A dramatic rapid response was an increase in (32)P-PA, together with its metabolic product diacylglycerol pyrophosphate (DGPP). AVR4 increased the levels of PA and DGPP in a Cf-4(+)-, time- and dose-dependent manner, while the non-matching elicitor AVR9 did not trigger any response. In general, PA signalling can be triggered by two different pathways: via phospholipase D (PLD), which generates PA directly by hydrolysing structural phospholipids like phosphatidylcholine (PC), or via PLC, which generates diacylglycerol (DAG) that is subsequently phosphorylated to PA by DAG kinase (DGK). To determine the origin of the AVR4-induced PA formation, a PLD-specific transphosphatidylation assay and a differential (32)P-labelling protocol were used. The results clearly demonstrated that most PA was produced via the phosphorylation of DAG. Neomycin and U73122, inhibitors of PLC activity, inhibited AVR4-induced PA accumulation, suggesting that the increase in DGK activity was because of increased PLC activity producing DAG. Lastly, evidence is provided that PLC signalling and, in particular, PA production could play a role in triggering responses, such as the AVR4-induced oxidative burst. For example, PLC inhibitors inhibited the oxidative burst, and when PA was added to cells, an oxidative burst was induced

Characterization of the transcriptional response to cell wall stress in Saccharomyces cerevisiae.

The cell wall perturbants Calcofluor white and Zymolyase activate the Pkc1¿Rho1- controlled Slt2p MAP kinase pathway in Saccharomyces cerevisiae. A downstream transcription factor of this pathway, Rlm1p, is known to control expression of about 20 cell wall-related genes. Global transcript analysis of Calcofluor white and Zymolyase treatment was performed to determine whether cell wall stress affects transcription of these and other genes. Transcript profiles were analysed using two recently developed algorithms, viz. REDUCE, which correlates upstream regulatory motifs with expression, and Quontology, which compares expression of genes from functional groups with overall gene expression. Both methods indicated upregulation of Rlm1p-controlled cell wall genes and STRE-controlled genes, and downregulation of ribosomal genes and rRNA genes. Comparison of these expression profiles with the published profiles of two constitutively active upstream activators of the Slt2p¿MAP kinase pathway, viz. Pkc1-R398A and Rho1-Q68A, revealed significant similarity. In addition, a new putative regulatory motif, CCC(N)10GGC, was found. In Zymolyase -treated cells a regulatory site was identified, ATGACGT, which resembles the AFT/CRE binding site. Interestingly, Sko1p, a downstream regulator of the high osmolarity pathway is known to bind to the AFT/CRE binding site, suggesting a possible role for the Hog1 pathway in the response to cell wall stress. Finally, using REDUCE, an improved version of the Rlm1 binding motif, viz. TA(W)4TAGM, was discovered. We propose that this version can be used in combination with REDUCE as a sensitive indicator of cell wall stress. Taken together, our data indicate that cell wall stress results in activation of various signalling pathways including the cell wall integrity pathway