The molecular basis of co-evolution between Cladosporium fulvum and tomato.

Cladosporiumfulvum is a semi-biotrophic pathogen, which causes leaf mold of tomato (Lycopersicon spp.). In our laboratory this pathosystem serves as a model to study gene-for-gene interactions between plants and pathogenic fungi (Joosten & De Wit 1999). Many avirulence (Avr) genes and matching resistance (CQ) genes have been cloned and we are now beginning to understand how their products can induce an array of plant defense responses, including the classic hypersensitive response (HR). Here, we will discuss the latest results of our molecular studies on this interaction. These include the isolation of: (i) two new Avr genes, Avr2 and Avr4E, (ii) the determination of the specificity determinants within the Cf-4 and Cf-9 genes by artificial domain swaps and introduction of point mutations, (iii) the analysis of polymorphism occurring in AVR9-responsive Cf genes occurring in natural populations of L. pimpinellifolium, and finally (iv) the description of an efficient method to identify early HR-related genes.

Efficient 13C/15N double labeling of the avirulence protein AVR4 in a methanol-utilizing strain (Mut+) of Pichia pastoris.

Cost effective 13C/15N-isotope labeling of the avirulence protein AVR4 (10 kDa) of the fungal tomato pathogen Cladosporium fulvum was achieved with the methylotrophic yeast Pichia pastoris in a fermentor. The 13C/15N-labeled AVR4 protein accumulated to 30 mg/L within 48 h in an initial fermentation volume of only 300 mL, while prolonged optimized overexpressions yielded 126 mg/L. These protein yields were 24-fold higher in a fermentor than in flask cultures. In order to achieve these protein expression levels, we used the methanol-utilizing strain (Mut+) of Pichia pastoris which has a high growth rate while growing on methanol as the only carbon source. In contrast, the methanol-sensitive strain (MutS) could intrinsically yield comparable protein expression levels, but at the expense of additional carbon sources. Although both strains are generally used for heterologous protein expression, we show that the costs for 13C-isotope labeling can be substantially reduced using the Mut+ strain compared to the MutS strain, as no 13C3-glycerol is required during the methanol-induction phase. Finally, nitrogen limitations were precluded for 15N-labeling by an optimal supply of 10 g/L (15NH4)2SO4 every 24 h.

Disulfide bond structure of the AVR9 elicitor of the fungal tomato pathogen Cladosporium fulvum: evidence for a cystine knot.

Disease resistance in plants is commonly activated by the product of an avirulence (Avr) gene of a pathogen after interaction with the product of a matching resistance (R) gene in the host. In susceptible plants, Avr products might function as virulence or pathogenicity factors. The AVR9 elicitor from the fungus Cladosporium fulvum induces defense responses in tomato plants carrying the Cf-9 resistance gene. This 28-residue beta-sheet AVR9 peptide contains three disulfide bridges, which were identified in this study as Cys2-Cys16, Cys6-Cys19, and Cys12-Cys26. For this purpose, AVR9 was partially reduced, and the thiol groups of newly formed cysteines were modified to prevent reactions with disulfides. After HPLC purification, the partially reduced peptides were sequenced to determine the positions of the modified cysteines, which originated from the reduced disulfide bridge(s). All steps involving molecules with free thiol groups were performed at low pH to suppress disulfide scrambling. For that reason, cysteine modification by N-ethylmaleimide was preferred over modification by iodoacetamide. Upon (partial) reduction of native AVR9, the Cys2-Cys16 bridge opened selectively. The resulting molecule was further reduced to two one-bridge intermediates, which were subsequently completely reduced. The (partially) reduced cysteine-modified AVR9 species showed little or no necrosis-inducing activity, demonstrating the importance of the disulfide bridges for biological activity. Based on peptide length and cysteine spacing, it was previously suggested that AVR9 isa cystine-knotted peptide. Now, we have proven that the bridging pattern of AVR9 is indeed identical to that of cystine-knotted peptides. Moreover, NMR data obtained for AVR9 show that it is structurally closely related to the cystine-knotted carboxypeptidase inhibitor. However, AVR9 does not show any carboxypeptidase inhibiting activity, indicating that the cystine-knot fold is a commonly occurring motif with varying biological functions.