S.S. Snoeijers

The Effect of Nitrogen on Disease Development and Gene Expression in Bacterial and Fungal Plant Pathogens

Successful colonisation of plants by pathogens requires efficient utilisation of nutrient resources available in host tissues. Several bacterial and fungal genes are specifically induced during pathogenesis and under nitrogen-limiting conditions in vitro. This suggests that a nitrogen-limiting environment may be one of the cues for disease symptom development during growth of the pathogens in planta. Here we review recent literature on the effect of nitrogen and nitrogen-regulated genes on disease development, caused by phytopathogenic bacteria and fungi. Furthermore, the potential influence of nitrogen-limitation or general nutrient limitation on several in planta-induced bacterial and fungal pathogenicity, virulence and avirulence genes will be discussed.

Expression of the Avirulence gene Avr9 of the fungal tomato pathogen Cladosporium fulvum is regulated by the global nitrogen response factor NRF1.

Here we describe the role of the Cladosporium fulvum nitrogen response factor 1 (Nrf1) gene in regulation of the expression of avirulence gene Avr9 and virulence on tomato. The Nrf1 gene, which was isolated by a polymerase chain reaction-based strategy, is predicted to encode a protein of 918 amino acid residues. The protein contains a putative zinc finger DNA-binding domain that shares 98% amino acid identity with the zinc finger of the major nitrogen regulatory proteins AREA and NIT2 of Aspergillus nidulans and Neurospora crassa, respectively. Functional equivalence of Nrf1 to areA was demonstrated by complementation of an A. nidulans areA loss-of-function mutant with Nrf1. Nrf1-deficient transformants of C. fulvum obtained by homologous recombination were unable to utilize nitrate and nitrite as a nitrogen source. In contrast to what was observed in the C. fulvum wild-type, the Avr9 gene was no longer induced under nitrogen-starvation conditions in Nrf1-deficient strains. On susceptible tomato plants, the Nrf1-deficient strains were as virulent as wild-type strains of C. fulvum, although the expression of the Avr9 gene was strongly reduced. In addition, Nrf1-deficient strains were still avirulent on tomato plants containing the functional Cf-9 resistance gene, indicating that in planta, apparently sufficient quantities of stable AVR9 elicitor are produced. Our results suggest that the NRF1 protein is a major regulator of the Avr9 gene.

Transcription of the avirulence gene Avr9 of the fungal tomato pathogen Cladosporium fulvum is regulated by a GATA-type transcription factor in Aspergillus nidulans

Abstract The avirulence gene Avr9 of the fungal tomato pathogen Cladosporium fulvum is highly induced during infection of tomato plants. Expression of the Avr9 gene can also be induced in vitro when cells are grown on synthetic liquid medium containing little or no nitrogen. The Avr9 promoter contains six copies of the sequence TAGATA and six additional copies of the core sequence GATA within 0.4 kb upstream of the translation start site. In the filamentous fungi Aspergillus nidulans and Neurospora crassa, these promoter sequences have been identified as the binding sites for a wide-domain GATA-type regulator (AREA in A. nidulans and NIT2 in N. crassa) involved in nitrogen utilization. Quantification of GUS activity of A. nidulans transformants containing a single copy of the fully active Avr9 promoter-uidA (GUS) reporter gene fusion in different areA backgrounds, following starvation for nitrogen, showed that induction of the Avr9 promoter is regulated similarly in A. nidulans and C. fulvum. This suggests that AREA can regulate the Avr9 promoter and that C. fulvum contains an AREA-like regulator that can bind to these specific sequence motifs. Comparison of the induction profiles of Avr9 and niaD showed that Avr9 expression is independent of NIRA, as is niaD expression upon nitrogen starvation. Studies with Avr9 promoter-uidA fusions in which all or most of these sequences had been deleted, showed that Avr9 promoter activity is dependent on the presence of these specific cis-regulatory elements, suggesting that they do indeed function in transcriptional regulation of the Avr9 gene.