Abstract
Protein phosphorylation cascades are universal in cell signaling. While kinome diversity allows specific phosphorylation events, relatively few phosphatases dephosphorylate key signaling proteins. Fungal mitogen activated protein kinases (MAPK), in contrast to their mammalian counterparts, often show detectable basal phosphorylation levels. Dephosphorylation, therefore, could act as a signal. In Cochliobolus heterostrophus, the Dothideomycete causing Southern corn leaf blight, ferulic acid (FA)—an abundant phenolic found in plant host cell walls—acts as a signal to rapidly dephosphorylate the stress-activated MAP kinase Hog1 (High Osmolarity Glycerol 1). In order to identify the protein phosphatases responsible, we constructed mutants in Hog1 phosphatases predicted from the genome by homology to yeast and other species. We found that Cochliobolus heterostrophus mutants lacking PtcB, a member of the PP2C family, exhibited altered growth, sporulation, and attenuated dephosphorylation in response to FA. The loss of the dual-specificity phosphatase CDC14 led to slow growth, decreased virulence, and attenuated dephosphorylation. Mutants in two predicted tyrosine phosphatase genes PTP1 and PTP2 showed normal development and virulence. Our results suggest that a network of phosphatases modulate Hog1’s dual phosphorylation levels. The mutants we constructed in this work provide a starting point to further unravel the signaling hierarchy by which exposure to FA leads to stress responses in the pathogen.
Highlights
Protein phosphorylation cascades are universal in cell signaling
Amino acid sequences of AfPtcB (A. fumigatus), ScCDC14 (Saccharomyces cerevisiae), ScPTP1, and MoPTP2 (M. oryzae) protein phosphatase genes [15,18,19] were retrieved from the Uniprot Database
Hog1 is well-studied in the context of high osmolarity stress, but the ferulic acid (FA)-induced pathway studied here has revealed new insights regarding the roles of Hog1 in pathogenicity and in developmental pathways
Summary
Signaling protein activity depends on a balance between protein phosphorylation and dephosphorylation. The vast array of kinases allows for a high degree of specificity in cellular phosphorylation events. A relatively small number of phosphatases are responsible for the dephosphorylation of key signaling proteins. Kinases comprise as much as 2% of the genome, and are responsible for the phosphorylation of more than 30% of the cellular proteins [2]. The specificity of phosphorylation is derived mainly from the high diversity of the kinome. The specificity of phosphatase activity depends, among other properties of the enzyme and substrates, on the amino acid to be dephosphorylated (e.g., Ser/Thr or Tyr; S/T or Y) and on the additional proteins mediating the phosphorylation/dephosphorylation reactions [4,5]
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